Cut running pliers are most useful until the last two thin strips are to be divided.
Tuesday, 4 February 2020
Breaking Apart the Last Two Thin Strips
For multiple thin strips of even widths, score all the strips first. Then break all the scored strips off the remaining sheet as one piece. Start the breaking process by breaking the scored sheet in the middle, then in the middle again, until there are only two to break apart.
Cut running pliers are most useful until the last two thin strips are to be divided.
At that point use two breaking pliers to hold each side of the two pieces of glass. The noses of the pliers should almost touch on either side of the score line. Apply pressure in a downward pivoting motion to break the pieces apart.
Cut running pliers are most useful until the last two thin strips are to be divided.
Breaking Tapered Pieces
Breaking thin pieces of glass can be tricky, but there are a few things you can do to help direct the break the way you want it to go.
Relieving scores made alongside curved and tapering pieces make the breaking more certain. A relieving score is one that is in addition to the primary score. This additional score will allow you to break the thin or tapering piece from the larger sheet safely, and then go on to break out the delicate piece.
The object is to always be breaking away less glass than is retained. The use of two breaking/grozing pliers, one on each side of the narrow pieces gives more even pressure than fingers or cut running pliers with wide jaws.
When breaking tapering pieces of glass you should normally grasp the thin end in fingers or pliers and run the score toward the thick end and ease the run of the score. When the score opens an initial distance, turn the glass end for end and run the score back to the opened one.
Relieving scores made alongside curved and tapering pieces make the breaking more certain. A relieving score is one that is in addition to the primary score. This additional score will allow you to break the thin or tapering piece from the larger sheet safely, and then go on to break out the delicate piece.
The object is to always be breaking away less glass than is retained. The use of two breaking/grozing pliers, one on each side of the narrow pieces gives more even pressure than fingers or cut running pliers with wide jaws.
When breaking tapering pieces of glass you should normally grasp the thin end in fingers or pliers and run the score toward the thick end and ease the run of the score. When the score opens an initial distance, turn the glass end for end and run the score back to the opened one.
Breaking Pieces from Large Sheets
Breaking a piece of glass from a large sheet is often a frightening prospect. It doesn't have to be. It is easier to cut a straight line piece from your larger sheet than it is to try to cut a curve. This describes a straight line cut from a large sheet of glass.
Use a cutting square or other non-slip straight edge to guide the cutter. You can push as in normal stained glass cutting, or you can draw the cutter toward you as glaziers do. In either case, the pressure needs to be even and the speed consistent.
When moving large scored sheets, avoid pulling the sheet by one end. The score may run suddenly and not always along the line. Instead, move the sheet with support on both sides of the score. After the glass is scored, you have choices about how to run the score.
One easy way to break off large pieces is to move the sheet so the scored line is just inside the edge of the bench. The biggest piece will be on the bench and the smaller piece in your hands. Give a quick, sharp downward push with both hands on the overhanging glass. This action will separate the piece from the main sheet. Having the glass score inside the bench edge gives you a place for the broken off piece to rest, rather than pivoting toward the floor.
Or you can slide the straight edge under the glass on one side of the score, and press firmly, but not sharply on each side of the score. The glass will break evenly along the score line. This is a more gentle method of breaking the glass. A variation on this is to place a couple of matchsticks or glass painting brushes at each end of the score and apply the pressure.
If the glass sheet is of a size that you can hold it in both hands with the score between, you can draw it off the bench, let it hang vertically, and bring your knee up briskly to hit the score line, and it will break easily. This is a showman’s way of breaking glass sheets when the score line is approximately centred on the sheet.
Cut running pliers often do not work very well for long straight scores on large sheets of glass. However, if you use this method, tapping at the start and at the end the score line before squeezing the running pliers will help the score to run the way you intend. This is sometimes the only way to achieve the break of the score. A note on the adjustment of cut running pliers is here.
Use a cutting square or other non-slip straight edge to guide the cutter. You can push as in normal stained glass cutting, or you can draw the cutter toward you as glaziers do. In either case, the pressure needs to be even and the speed consistent.
When moving large scored sheets, avoid pulling the sheet by one end. The score may run suddenly and not always along the line. Instead, move the sheet with support on both sides of the score. After the glass is scored, you have choices about how to run the score.
One easy way to break off large pieces is to move the sheet so the scored line is just inside the edge of the bench. The biggest piece will be on the bench and the smaller piece in your hands. Give a quick, sharp downward push with both hands on the overhanging glass. This action will separate the piece from the main sheet. Having the glass score inside the bench edge gives you a place for the broken off piece to rest, rather than pivoting toward the floor.
If the glass sheet is of a size that you can hold it in both hands with the score between, you can draw it off the bench, let it hang vertically, and bring your knee up briskly to hit the score line, and it will break easily. This is a showman’s way of breaking glass sheets when the score line is approximately centred on the sheet.
Cut running pliers often do not work very well for long straight scores on large sheets of glass. However, if you use this method, tapping at the start and at the end the score line before squeezing the running pliers will help the score to run the way you intend. This is sometimes the only way to achieve the break of the score. A note on the adjustment of cut running pliers is here.
Revised 30.12.24
Breaking glass with your fists
No, this is not about punching the glass – a dangerous approach. But it is a two-fisted approach to holding glass to break it.
For scores with significant, but not necessarily equal, amounts of glass on each side of the score this is a quick simple approach to breaking glass. After scoring, raise one edge of the glass and put your fingers under the glass on each side of the score. Curl you fingers into your palm, and put your thumbs on top of the glass. Turn your wrists outward and the glass will break cleanly.
With practice, the initial part of a curved score can be run by applying light pressure. Then you can turn the glass around and run the score from the other end to the opened score. This avoids lots of tapping and gives clean edges to the cut glass. It is just as simple as using cut running pliers and avoids the flare often associated with using cut running pliers.
This technique works best with glass that has at least 50mm each side of the score and on gently curved lines. For tight curves and narrow strips other methods need to be used.
For scores with significant, but not necessarily equal, amounts of glass on each side of the score this is a quick simple approach to breaking glass. After scoring, raise one edge of the glass and put your fingers under the glass on each side of the score. Curl you fingers into your palm, and put your thumbs on top of the glass. Turn your wrists outward and the glass will break cleanly.
With practice, the initial part of a curved score can be run by applying light pressure. Then you can turn the glass around and run the score from the other end to the opened score. This avoids lots of tapping and gives clean edges to the cut glass. It is just as simple as using cut running pliers and avoids the flare often associated with using cut running pliers.
This technique works best with glass that has at least 50mm each side of the score and on gently curved lines. For tight curves and narrow strips other methods need to be used.
Revised 30.12.24
Care of Your Soldering Iron Tip
Wipe your hot iron tip on a wet sponge on a regular basis while soldering. It must be done on a natural sponge, not a plastic based one. This should be a quick pass, rather than a lingering one to avoid cooling the tip of the soldering bolt. This keeps the tip clean of carbon and other contaminants that can reduce the effective heat from the tip.
There are also brass wool tip cleaners. These are a bit more aggressive than the sponge, but do not cool the tip.
If you have any dark gunk build up that won't come off on the sponge, rub the hot iron tip against a block of sal ammoniac until the block clears. If the dirt is difficult to remove with the sal ammoniac, use a brass wire brush to scrape the dirt off and then go back to the sal ammoniac block. When it is clean, add a touch of solder to re-tin the tip, and then wipe against your wet sponge.
Remember, all this is done while the iron is hot, so be careful.
Other links to Soldering Iron Maintenance:
https://glasstips.blogspot.com/2019/11/soldering-iron-maintenance.html
https://glasstips.blogspot.com/2010/01/maintenance-of-soldering-bits-periodic.html
https://glasstips.blogspot.com/2009/12/soldering-bit-maintenance-wiping-bit.html
https://glasstips.blogspot.com/2009/12/soldering-bit-maintenance-tinning.html
If you have any dark gunk build up that won't come off on the sponge, rub the hot iron tip against a block of sal ammoniac until the block clears. If the dirt is difficult to remove with the sal ammoniac, use a brass wire brush to scrape the dirt off and then go back to the sal ammoniac block. When it is clean, add a touch of solder to re-tin the tip, and then wipe against your wet sponge.
Remember, all this is done while the iron is hot, so be careful.
Other links to Soldering Iron Maintenance:
https://glasstips.blogspot.com/2019/11/soldering-iron-maintenance.html
https://glasstips.blogspot.com/2010/01/maintenance-of-soldering-bits-periodic.html
https://glasstips.blogspot.com/2009/12/soldering-bit-maintenance-wiping-bit.html
https://glasstips.blogspot.com/2009/12/soldering-bit-maintenance-tinning.html
Revised 30.12.24
Polishing Panels with Paint and Enamels on the Glass
Do not use black patina on the lead/solder lines on your finished work if there is any painted glass in the panel whether leaded or foiled. This relates to traditional painting on glass, using vitreous paints, fired at ca. 670C and to cold paints often cured in a domestic oven.
When using enamels within the painting, do not let any patina come in contact with the finished production. The patina will etch out all the enamel colour. The patina will etch off the outer layer, either removing the shiny top layer of paint, or the delicate lines of detail work altogether. Copper patina takes a little of the paint off, but not nearly as badly as the black patina. Also patinas can often impart a subtle rainbow effect on the glass near the solder lines.
Instead, brush the panel with a natural bristle brush, as used for putty clean up, and polish.
Silver stains that have been properly held at the maturing temp, should withstand any patina application, as they have become incorporated at the molecular level with the glass.
When using enamels within the painting, do not let any patina come in contact with the finished production. The patina will etch out all the enamel colour. The patina will etch off the outer layer, either removing the shiny top layer of paint, or the delicate lines of detail work altogether. Copper patina takes a little of the paint off, but not nearly as badly as the black patina. Also patinas can often impart a subtle rainbow effect on the glass near the solder lines.
Instead, brush the panel with a natural bristle brush, as used for putty clean up, and polish.
Silver stains that have been properly held at the maturing temp, should withstand any patina application, as they have become incorporated at the molecular level with the glass.
Turning Panels
Panels should be turned by supporting as much of the panel as possible. In general this means that the panel should be moved until about half of it is off the bench and supported by one hand. Then pivot the panel on the edge of the bench until it is vertical. During this process, the other hand should be supporting the other edge. Pivot until vertical. Lift and set it on the bench. Turn it around, keeping it vertical. Lift it off the bench and set the middle against the edge of the bench with one hand on each otherwise unsupported edge. Pivot the panel on the edge and slide it back on the bench.
If the panel is going to be a large one, make it on a board placed on top of your bench. Then when it is time to turn the panel, you can tip the board, set the panel together with the board on the floor. Move the board to the other side of the panel, turn the board around, placing it against the edge of the bench and raise it while pivoting it on the bench. Additional help is to have two short pieces of wood on the floor to set the panel and board on, so you can get your fingers under easily and without getting them trapped.
If you have the space and spare boards, you can place a second board on top of the panel. Make sure the panel is at the edge of the boards next to you. You can then, with the help of another person, turn the whole panel in one movement (although your arms will be in a bit of a twist). This removes the danger of the panel wobbling too much while shifting the supporting board.
A panel of any size with one or more long lines going through the panel should be made on a board, so that it can be turned without the danger of breaking any of the glass or of the panel folding along the lead lines.
If the panel is going to be a large one, make it on a board placed on top of your bench. Then when it is time to turn the panel, you can tip the board, set the panel together with the board on the floor. Move the board to the other side of the panel, turn the board around, placing it against the edge of the bench and raise it while pivoting it on the bench. Additional help is to have two short pieces of wood on the floor to set the panel and board on, so you can get your fingers under easily and without getting them trapped.
If you have the space and spare boards, you can place a second board on top of the panel. Make sure the panel is at the edge of the boards next to you. You can then, with the help of another person, turn the whole panel in one movement (although your arms will be in a bit of a twist). This removes the danger of the panel wobbling too much while shifting the supporting board.
A panel of any size with one or more long lines going through the panel should be made on a board, so that it can be turned without the danger of breaking any of the glass or of the panel folding along the lead lines.
Straightening the came
Before using the came it is important to straighten it. This increases the stability of the came during the leading process. Most often nowadays, you use a lead vice. This operates similarly to a cleat on a sailing boat. The more strain that is applied, the tighter the vice grips the came.
You place the end of the came into the vice so that the came appears at the back of the vice. Give the top of the vice a firm tap with your pliers to set the teeth into the came. Grasp the other end of the came with the pliers, and put one foot behind you to brace yourself if the came does slip out of the vice. Draw the came toward yourself until you can see the lead is straight and any kinks have straightened.
Take the came out of the vice and keep it straight. You transport it by grasping each end and keep the came under tension until you get it to the destination. It is often easiest to cut the full length in half before moving it, as it will not then be longer than your arms can stretch.
Remember, this process is to straighten the came to give pleasing lines in the leaded panel. It is not stretching the lead. Stretching the came can weaken the lead.
You place the end of the came into the vice so that the came appears at the back of the vice. Give the top of the vice a firm tap with your pliers to set the teeth into the came. Grasp the other end of the came with the pliers, and put one foot behind you to brace yourself if the came does slip out of the vice. Draw the came toward yourself until you can see the lead is straight and any kinks have straightened.
Take the came out of the vice and keep it straight. You transport it by grasping each end and keep the came under tension until you get it to the destination. It is often easiest to cut the full length in half before moving it, as it will not then be longer than your arms can stretch.
Remember, this process is to straighten the came to give pleasing lines in the leaded panel. It is not stretching the lead. Stretching the came can weaken the lead.
Revised 30.12.24
Sunday, 2 February 2020
Dressing the Cames - part 2
Of course, it is not enough just to dress the came at the start. There is an analogous procedure after the whole panel has been leaded, soldered and cemented.
In this instance the term ‘dressing the cames’ means to close or bend the leaves/flanges of the came toward the glass. It provides a neat rounded appearance to the lines, traps the cement you have already added, presents less area for the rainwater to collect, and makes polishing easier. It is also the time when you may break the glass by putting too much pressure on the glass, so be careful!
Dressing the cames is done with an oyster knife or fid. It is best to avoid metal and better to use wood sticks or plastic tools. The pressure is placed on the came rather than the glass. Run the fid lightly at a shallow angle along each flange of the came. It is helpful to use a finger of your other hand to guide the fid along the cames. You may want to do this several times, as repeated light pressure will cause the flanges of the came to move gently toward the glass with less risk of breaking the glass. This can only be done while the cement is pliable. If it is done after polishing, you will need to re-do the polishing, as it will make the edges of the came silvery rather than shiny black.
In this instance the term ‘dressing the cames’ means to close or bend the leaves/flanges of the came toward the glass. It provides a neat rounded appearance to the lines, traps the cement you have already added, presents less area for the rainwater to collect, and makes polishing easier. It is also the time when you may break the glass by putting too much pressure on the glass, so be careful!
Revised 30.12.24
Wednesday, 15 January 2020
Odd Schedules
Schedules
appear on the internet which do not seem to have a logical sequence in the
firing schedule. Some have multiple
soaks at intervals up to 540°C. Others
have kind of dance toward the top temperature – slow, quick, slow. Some initially cool at a given rate and then
slow to about half that initial rate.
Multiple soaks
These
schedules have been referred to as catch-up schedules. They tend to look something like this:
200°C to 150°C for 20 minutes
250°C to 300°C for 20 minutes
300°C to 590°C for 20 minutes
50°C
to 677°C for 30 minutes
330°C to 804°C for 10 minutes
AFAP
to 482°C for 60 minutes
60°C
to 370°C for 0 minutes
Off
The
justification for the first two soaks is given as allowing the glass to catch
up to the air temperature. It would be
much safer for the glass to have a moderate steady advance in temperature
rather than risking the heat shocking of the glass. You could achieve the same work in the same
amount of time by altering the rate of advance to a single one of 198°C to
590°C. This achieves the same
temperature in the same amount of time, but has less risk of heat shock, as
there is a steady input of heat.
Secondly, if the glass can survive the initial rate of heat up without breaking, there is no need to soak at an arbitrary temperature. The first relevant point where a change in temperature makes sense is above the softening point, which for most fusing glasses is about 540
Secondly, if the glass can survive the initial rate of heat up without breaking, there is no need to soak at an arbitrary temperature. The first relevant point where a change in temperature makes sense is above the softening point, which for most fusing glasses is about 540
Slow, quick, slow
This kind of schedule alters rates up
and down with little justification as far as I can see. This is an example:
139°C to 560°C for 30 minutes
222°C to 621°C for 30 minutes
139°C to 786°C for 15 minutes
9999 to 515°C for
120 minutes
60°C to 427°C for
10 minutes
115°C to 350°C for 10 minutes
The question for me is why the slow
down to top temperature. There is a lot of heat work being put into the glass,
so that the higher top temperature may not be required. The slower rate from 621°C does allow a form
of a bubble squeeze to occur, but is not the traditional one. A 139°C rate from 621°C to 677°C with a soak would be faster than usual,
but may be acceptable. I would prefer 50°C
per hour with a 30-minute soak at the end.
Then advancing at 300°C per hour to top temperature. The anneal soak and cool of this schedule are
acceptable, even though different than I would do it.
Erratic Slumping Schedule
The fusing schedule above was
followed by this slumping schedule:
83°C to 148°C 15 minutes
167°C to 590°C 10 minutes
83°C to 720°C 10 minutes
222°C to 410°C 120 minutes
83°C to 427°C 10 minutes
This schedule seems to have
a catch-up phase in that it goes at half speed for the first 148°C and then
doubles the speed to 590°C (a little above the brittle phase of the
glass). It then slows the rate and
continues that to a very high slump temperature. It is, of course, necessary to have a slower
rate of advance in the slumping than the fusing, as the piece is now thicker. Slowing
the rate of advance as much as in this should be able to achieve the slump at
around 620°C (100°C) less than the target temperature used by the
schedule.
Once the top temperature
soak is finished, a very slow cool to the annealing soak is used in this
schedule. This is not ideal as it
invites devitrification to form. The
kiln and its contents should be allowed to cool as quickly as possible to the
temperature equalisation soak at the annealing point.
The schedule then uses an
annealing soak temperature 100°C below that used for the fusing. This does not
make sense. The annealing soak should be at the same temperature for both
firings. The length of the soak is not
in question, but the early turn off the kiln at 427°C is questionable. The
anneal cool of the fused piece extended down to 350°C. The anneal cool on slumping should be almost
the same as the fuse. Almost all anneal
cools extend to 370°C at least.
Anneal Cools
Some
anneal cools have erratic rather than progressive cooling. In this example the early part of the
schedule is eliminated:
……………..
AFAP to 482°C
120 minutes
110°C to 427°C
0 minutes
55°C to 370°C
0 minutes
200°C to 100°C
0 minutes
off
Here
the schedule is faster in the most critical part of the anneal cool than in the
next, cooler part. This will not provide
as good an anneal as if the first two segments after the equalisation soak were
reversed. Start slowly in the anneal
cool and then you can speed up (approximately twice the previous segment rate)
on each of the following segments.
Rationale
This
critique of the schedules above is not to batter anyone. It is to make clear that there needs to be a
conscious rationale for each of the segments in relation to the others. If you take a schedule from a source, it is a
good idea to see if there is a reason for each segment and how it relates to
the next.
·
The scheduling must take account of the
nature of the glass. Glass is a poor
conductor of heat and needs steady moderate input of heat.
·
Glass is brittle until approximately 55°C
above the annealing temperature when you can accelerate the rate of advance.
·
Time is required to allow air out from
between the layers of glass. This usually done in the range of 620°C to 675°C
and is known as the bubble squeeze.
·
You need to go relatively quickly through the
devitrification range of temperatures – approximately 700°C to 760°C - both up and down.
·
Glass needs a temperature equalisation soak
at the annealing point (or nearby) related to its thickness.
·
The rate of cooling needs to be
progressive. The first 55°C below the
annealing soak is the most important.
·
Cooling rates must be related to thickness.
·
The second cooling rate can be up to double
the initial one.
·
The final cooling rate can be double the
previous one.
·
The rate of firing will affect the required
top temperature.
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