Hake brush

Bamboo handle hake brush

The hake (pronounced hah–kay) brush was developed in the far east.  It has several variations – the original consisted of a group of bamboo brushes bound together in a line.  These are still made and used. Many modern hake brushes have a broad wooden handle with a wide line of hairs.  These brushes are made of very fine, soft hairs - often goat hair is used. 

Flat wooden hake brushes

The flat hake brushes are most often cheaper and in a wider variety of sizes than the bamboo ones.  I prefer the bamboo for the feel in the hand that the broad handle gives.  With the longer hairs, it holds more moisture and delivers even amounts of kiln wash even with long strokes. 

Use

These brushes can hold a lot of moisture and deliver it evenly.  This makes it good for laying  down large areas of even colour in watercolours, and in glass painting. The same characteristic makes it very good for coating shelves with kiln wash.  The brush should be filled liberally with the paint or kiln wash. The brush should be gently shaken to remove any excess. Hold the brush nearly vertical and let the bristles barely touch the surface as you move along in smooth sweeps across the surface.  This allows the kiln wash to be evenly spread with very few brush marks.

Maintenance

One drawback of these brush is that the fine soft hairs are difficult to bind into the ferrule.  This results in the brushes often shedding hairs onto the shelf as it is being coated. A tip I learned from Bullseye is to treat the new hake brush with superglue at the base of the hairs. It does not have to be super glue.  It can be any runny glue, or diluted PVA.  I prefer super glue, even though it is reported to have some sensitivity to moisture. You can work the glue into the centre by using a needle to poke at the hairs to move the glue toward the centre of the bristles.  The glue binds the hairs in addition to the binding at the ferrule, and so keeps the brush from shedding. 

I did this on my bamboo handle hake brush a couple of years ago and it is not yet shedding hairs during applications of kiln wash.

Make sure you clean the bristles immediately after using to avoid any material drying among the hairs and causing them to break when next used.  To clean the brush, you only need running water run through the bristles.  Do not scrub the bristles against anything.  The hairs are delicate.  Set the brush aside horizontally to allow water to drip off and the hairs to dry.  Setting the brush upside down when wet allows water into the bindings of the hairs.  Putting it with the hairs down onto a surface deforms the hairs, making it difficult to straighten them later.

A hake brush is among the most useful tools to put kiln wash onto shelves and moulds because it holds so much moisture.  It does require maintenance to ensure the hairs do not shed and that the delicate hairs are not broken.

Needle Points

Often fused glass has prickles or needle points around the edges and especially at corners after firing.

This illustration is from Glass Fusing Made Easy

The nature of glass and its interaction with the separators is the cause.  As you heat glass it expands. Once the cooling starts, the glass contracts. Often a particle of the glass sticks to the separator while the rest continues to contract. This dragging of the glass along the separator results in the creation of little sharp points developing as the glass retreats to its final dimensions.

The best solution I have found to reducing the points at corners is to blunt any points or corners before assembly. Only a tiny amount of glass needs to be removed from the corners to reduce the possibility of these points being developed.

Small needle points can also develop along the sides of the glass too.  These are more difficult to avoid.  The most successful method for me is to use a loose separator.  This can be Thinfire, Papyros or a fine dusting of alumina hydrate or powdered kiln wash.  Although less widely available, talc can be used. Talc is known to be carcinogenetic with high exposure, so breathing protection is needed. All these powders provide enough lubrication to allow the runny glass to slide without sticking. 

Of course, you can use boron nitride, which is very slippery, but the cost of it makes it expensive in comparison to the other methods, including using fine diamond pads to remove the needles.

An additional consideration is the temperature you use.  The higher the temperature, the more the expansion.  Expansion rates are almost exponential above the brittle phase of the glass.  Reducing the temperature by 20C and doubling time or more means the glass does not expand so much and the additional time allows the desired profile to be achieved.  

Of course, paying attention to volume control - using 6mm or more thickness - will help to reduce the needle points.  A 3mm sheet both expands and becomes thicker at the edges by drawing more glass from the interior and the edge while attempting to reach 6mm.  This means there is an increase in the needling effect.  Although a 6mm piece retreats on cooling, it does not have the additional thickening effect of a 3mm piece.  Even a 9mm piece retreats on cooling, although the final piece has a larger area than at the start. 

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There are various preventive measures that can be taken to avoid needle points on fused glass.  These range from altering the edges of the glass, using fibre papers that turn to powder, using refractory powders, or boron nitride. Post firing solutions relate to cold working.

Deep moulds

What is the relation between the diameter and depth of a mould and the diameter of the blank to be slumped into it?  Is there an equation? For example, a mould of 6.5 inches diameter and 3.5 inches deep.

The above example is a deep mould. When compared to the diameter it is more than half the diameter deep. It is a difficult style of mould for many kiln formers.

To explain, some of the differences between deep and shallow moulds needs to be noted.  Deep and shallow are descriptions for the relationship of the span (or space from side to side) to the depth (the distance the glass must slump into the mould).

A 150mm square bowl that is 50mm deep

       Shallow moulds are easier as there are no steep curves to form into. Gentle compound curves generally provide no greater challenges. Shallow moulds with angular corners or abrupt changes of curve to the bottom are moderately more difficult than simple curves.

       Deep moulds are difficult. An example of this is the successful deep vessels of Karl Harron where it is necessary to form the glass through three successively deeper moulds.  His vessels are often deeper than the diameter, making them among the most difficult kilnformed vessels to achieve except roll-ups, which are a combination of kilnformed and blown.

The difficulties with deep moulds are multiple.

·        The glass must stretch more than in a shallow one where only a change in shape is required.

·        As the depth increases, the upper rim is heated more than the centre, being closer to the heat source.

·        The edge develops needle points and stretch marks.

·        The blank becomes smaller in diameter than the rim of the mould.

·        As it slips down into the mould the softened rim of the glass catches on the mould and produces stretch marks.

·        If the upper rim is significantly hotter than the centre, needle points are left on the edge where it catches the mould and stretches to very thin points.

Because of the depth, you will find the finished glass diameter will be smaller than the rim of the mould.

An example of an apparently shallow bowl until you take account of the size of the inner part, making this a deep bowl.  

Over hanging blanks

Do not be tempted to make the blank much bigger than the mould. The most you should risk is 12mm larger diameter than the mould. This means only 6mm is over the edge of the mould.

In deep moulds where I am doing only one slump, I find better success in making the glass slightly smaller than the mould diameter, so the glass does not hang up on the edges.

A blank larger than this mould is likely to hang up on the narrow rim of the mould, and the blank should be slightly smaller than the interior of the rim.

Multiple Moulds

Because deep moulds are difficult to do in one firing, it is best is to start with a larger blank in a shallower mould and transfer the formed piece to successively deeper moulds. 

Some experimentation will be needed to determine the starting size, of course.  A guide would be to measure the length of inside curve of the deep mould from one edge along to the bottom and up to the other side with a flexible measuring tape.  This will give the approximate diameter needed for the blank.  

I start off with a blank of about 25mm less than the measured diameter.  This is to allow for the stretching that is going to occur even at low temperatures. Cut and fuse a clear blank for the test. Find a shallow ball mould of that diameter or larger and slump into it. A second mould may be needed that is deeper and of the size of the now slumped piece with a smaller than original span.  By this second slumping, the piece may fit into the deep mould for the final slumping.

Firing for deep moulds

To fire deep moulds successfully, you need to go slowly (maybe only 75C per hour for 6 mm) up to a low slumping temperature (maybe 630C for 60 to 90 minutes).  This slow rate of advance allows the heat to be distributed evenly throughout the piece.  A low temperature avoids over-heating the rim of the piece during the slumping.  The long soak allows the glass to gradually conform to the shape of the mould without excessive marking.

It is important to monitor the firing of deep moulds.  It is common for the glass to slump unevenly.  Peeking and being prepared to reach into the kiln to shift the glass or even tilt the mould so the lowest part is elevated to receive more heat is important to succeed in slumping into deep moulds. 

Deep moulds require a lot of effort to achieve successful results. You must give special attention to temperatures, rates of firing, soaks and consider the use of multiple slumps – each deeper than the previous.

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