Difference between pages "How to Pack Food in Glass" and "How to Dye Fabric / Textile with Natural Colors"

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(The process of dyeing)
 
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=Packaging Foods in Glass - Technical Brief=
+
=Natural Dyeing of Textiles - Technical Brief=
 
 
<div class="booktext">
 
  
 +
==Introduction==
  
</div>
 
  
==Introduction==
+
Dyeing is an ancient art which predates written records. It was practised during the Bronze age in Europe. Primitive dyeing techniques included sticking plants to fabric or rubbing crushed pigments into cloth. The methods became more sophisticated with time and techniques using natural dyes from crushed fruits, berries and other plants, which were boiled into the fabric and gave light and water fastness (resistance), were developed.
 
 
<div class="booktext">
 
  
This technical brief is intended to advise small-scale producers on the methods and equipment needed to package foods in glass jars and bottles. For a more detailed account of the types of foods that can be packaged in glass, the properties of glass containers, label design and production and the economic implications of introducing glass packaging the reader is advised to consult 'Appropriate Food Packaging' by P J Fellows and B L Axtell, ILO Technical Memorandum, Published by TOOL Publications, Sarphatistraat 650, 1018 AV Amsterdam, The Netherlands, 1993 (ISBN 90 70857 28 6).
+
Some of the well known ancient dyes include madder, a red dye made from the roots of the ''Rubia tinctorum'', blue indigo from the leaves of ''Indigofera tinctoria'', yellow from the stigmas of the saffron plant, and dogwood, an extract of pulp of the dogwood tree. The first use of the blue dye, woad, beloved by the Ancient Britons, may have originated in Palestine where it was found growing wild. The most famous and highly prized colour through the age was Tyrian purple, noted in the Bible, a dye obtained from the spiny dye-murex shellfish. The Phoenicians prepared it until the seventh century, when Arab conquerors destroyed their dyeing installations in the Levant. A bright red called cochineal was obtained from an insect native to Mexico. All these produced high-quality dark colours. Until the mid-19th century all dyestuffs were made from natural materials, mainly vegetable and animal matter.
  
'''General outline of procedures'''
+
Today, dyeing is a complex, specialised science. Nearly all dyestuffs are now produced from synthetic compounds. This means that costs have been greatly reduced and certain application and wear characteristics have been greatly enhanced. But many practitioners of the craft of natural dying (i.e. using naturally occurring sources of dye) maintain that natural dyes have a far superior aesthetic quality which is much more pleasing to the eye. On the other hand, many commercial practitioners feel that natural dyes are non-viable on grounds of both quality and economics. In the West, natural dyeing is now practised only as a handcraft, synthetic dyes being used in all commercial applications. Some craft spinners, weavers, and knitters use natural dyes as a particular feature of their work.
  
 
<center>
 
<center>
  
[[Image:Food_Packaging_Glass_1.jpg]]
+
[[Image:Indigo01.gif]]<br /> Figure 1: Indigo
  
</center></div>
+
</center>
  
==Inspection and preparation of containers==
+
In many of the world’s developing countries, however, natural dyes can offer not only a rich and varied source of dyestuff, but also the possibility of an income through sustainable harvest and sale of these dye plants. Many dyes are available from tree waste or can be easily grown in market gardens. In areas where synthetic dyes, mordants (fixatives) and other additives are imported and therefore relatively expensive, natural dyes can offer an attractive alternative.
  
<div class="booktext">
+
The knowledge required for sourcing and extracting such dyes and mordants is, however, often not available as extensive research work is required to identify suitable plants, minerals, etc. In Zambia for example, there is a wealth of plants available for producing natural dyes, but due to lack of knowledge of the processes involved in harvesting and processing the plants, little use is made of this natural resource. In some countries, such as India, Nigeria and Liberia, where this research has been carried out, or where there exists a tradition of natural dyeing, natural dyes and mordants are used widely.
  
All incoming glass containers must be inspected for cracks, chips and small bubbles in the glass. New jars and bottles should be rinsed in clean water, chlorinated if necessary by adding 2-3 drops of household bleach per litre of water.
+
</div>
  
Second hand bottles must be thoroughly inspected, both by looking for chips etc and also by smelling the containers to make sure that they have not been used for storing kerosene or poisonous chemicals (insecticides etc). All contaminated containers should be removed and not used for foods.
+
==Types of textiles suitable for dying==
  
Second hand containers should be soaked in a 1% solution of caustic soda with detergent to remove old labels. The interior should be cleaned with a bottle brush (Figure 1) and then rinsed thoroughly. Rinsing is time consuming and can be speeded up using a bottle rinser (Figure 2).
+
<div class="booktext">
  
<center>
+
Natural dyes can be used on most types of material or fibre but the level of success in terms of fastness and clarity of colour varies considerably. Users of natural dyes, however, tend to also use natural fibres, and so we will look in more detail at this group. Natural fibres come mainly from two distinct origins, animal origin or vegetable origin. Fibres from an animal origin include wool, silk, mohair and alpaca, as well as some others which are less well known. All animal fibres are based on proteins. Natural dyes have a strong affinity to fibres of animal origin, especially wool, silk and mohair and the results with these fibres are usually good. Fibres of plant origin include cotton, flax or linen, ramie, jute, hemp and many others. Plant fibres have cellulose as their basic ingredient. Natural dyeing of certain plant based textiles can be less successful than their animal equivalent. Different mordanting techniques are called for with each category. When a blend of fibre of both animal and plant origin is being dyed, then a recipe should be chosen which will accentuate the fibre which is required to be dominant.
  
[[Image:Food_Packaging_Glass_2.gif]]<br /> Figure 1: Bottle brush
+
</div>
  
</center><center>
+
==Equipment needed for home dyeing and very small-scale commercial dyeing==
  
[[Image:Food_Packaging_Glass_3.gif]]<br /> Figure 2: A bottle rinser
+
<div class="booktext">
  
</center>
+
Most equipment needed for dyeing fabrics at home, or at the very small-scale commercial level, can be found in almost any market place throughout the world. The following is a list of the equipment requirements and a brief explanation of their use.<br />
  
Many foods that are packaged in glass are then heat processed and for these it is usual to hot-fill the containers (fill at 80°C or above). Glass has to be heated and cooled carefully to avoid the risk of breakage and therefore it is usual to pre-sterilise containers before hot filling. This can be done by placing bottles/jars in a large pan of warm water and heating it to boiling. The containers are boiled for 10 minutes and then removed for immediate filling and sealing.
+
<blockquote>
  
Alternatively a steamer (Figure 3) can be constructed and bottles/jars steamed for 1-2 minutes. This uses less energy and saves considerable amounts of time compared to using boiling water. However, care is needed to make sure that the containers are not heated too quickly, as they will break. Any weak containers will also break at this stage and bottle sterilisation should therefore be carried out away from the food production area to avoid the risk of contamination by broken glass.
+
• ''Heat source''. This can be any type of cooking stove; gas, wood, kerosene, charcoal, electricity. This is used for heating the liquid used during mordanting and dyeing.
  
Tongs as shown in Figure 3 should be used in all cases when handling hot containers.
+
• ''Pestle and mortar''. Used for milling the natural dye or minerals, where this is called for.
  
<center>
+
• ''Mordanting and dyeing pans''. Stainless steel or enamel pans are the most suitable for dyeing. The size of pan depends upon the quantities of fabric that will be dyed. Do not use pans made from copper, aluminium or iron, unless absolutely necessary, as these metals have properties which can change the colour of the dye.
  
[[Image:Food_Packaging_Glass_4.gif]]<br /> Figure 3: A steamer
+
• ''tirring rods''. Stainless steel or glass rods are best as they can be cleaned and used for different colour dyes. If wooden stirring rods are used then there should be a different spoon for each colour.
  
</center>
+
• ''Thermometer''. This is used to measure the temperature of the liquid during mordanting and dyeing. A long thermometer (to reach the liquid at the bottom of the pan) is preferred, with a range of 0 - 100oC (32 - 210oF).
  
For foods that are cold filled and then heat processed it is not necessary to pre-sterilise the container. For cold filled foods that are not subsequently heated it is essential to make sure that the jar or bottle is sterilised by one of these methods to prevent contamination of the product by any micro-organisms on the glass.
+
• ''Measuring jugs''. These are used to measure the quantities of liquid called for in the recipe. Sometimes precise quantities are called for.
  
</div>
+
• ''Storage containers''. Used for storing the dyestuffs and mordants. Large glass and plastic jars are ideal. Some mordants and dyes are sensitive to light and should therefore be stored in sealed light-proof containers.
  
==Filling==
+
• ''Plastic bowls and buckets''. A variety of plastic bowls or buckets of varying sizes are useful when wetting or rinsing fabrics.
  
<div class="booktext">
+
• ''Strainer''. Used for straining the liquid off the dyestuff in the dyebath.
  
Most foods that are packaged in glass are either liquids, such as drinks and syrups or thicker pastes such as sauces, chutneys etc.
+
• ''Weighing scales''. Used for obtaining the correct quantities as specified in the recipe. A scales with metric and imperial measurement is useful as conversions from one system to the other are not then needed.
  
There are basically two types of filling equipment: those used for solid foods and others for liquid foods.
+
• ''Protective equipment''. Gloves for holding hot pans will prevent burns. An apron will protect your clothing. Rubber gloves will prevent skin irritation caused by mordants, and will also prevent you from dyeing your hands. A face mask can cut down the amount of fumes or powder inhaled during the dyeing process.
  
</div>
+
</blockquote></div>
  
==Solids fillers==
+
==Mordants==
  
 
<div class="booktext">
 
<div class="booktext">
  
There are few paste filling machines that are cheap enough for small-scale processors but an example of one type (a piston filler) is shown in Figure 4. Most producers fill by hand and although this is slow it can be speeded up by the use of a simple funnel and rod (Figure 5).
+
Few natural dyes are colour-fast with fibres. Mordants are substances which are used to fix a dye to the fibres. They also improve the take-up quality of the fabric and help improve colour and light-fastness. The term is derived from the Latin ''mordere,'' to bite. Some natural dyes, indigo for example, will fix without the aid of a mordant; these dyes are known as ‘substantive dyes’. Others dyes, such as madder and weld, have a limited fastness and the colour will fade with washing and exposure to light.
  
<center>
+
Traditionally, mordants were found in nature. Wood ash or stale urine may have been used as an alkali mordant, and acids could be found in acidic fruits or rhubarb leaves (which contain oxalic acid), for example. Nowadays most natural dyers use chemical mordants such as alum, copper sulphate, iron or chrome (there are concerns, however about the toxic nature of chrome and some practitioners recommend that it is not used).
  
[[Image:Food_Packaging_Glass_5.gif]]<br /> Figure 4: A piston filler
+
Mordants are prepared in solution, often with the addition of an ‘assistant’ which improves the fixing of the mordant to the yarn or fibre. The most commonly used mordant is alum, which is usually used with cream of tartar as an additive or assistant. Other mordants are:<br />
  
</center><center>
+
<blockquote>
  
[[Image:Food_Packaging_Glass_6.gif]]<br /> Figure 5: Funnel and rod
+
• Iron (ferrous sulphate)<br /> • Tin (stannous chloride)<br /> • Chrome (bichromate of potash)<br /> • Copper sulphate<br /> • Tannic acid<br /> • Oxalic acid
  
</center>
+
</blockquote>
  
In the case of solids such as fruit that is packed in syrup, the solid pieces are first placed in the jar by hand and the liquid is then filled using a liquids filler.
+
<br /> Using a different mordant with the same dyestuff can produce different shades, for example;<br />
  
</div>
+
<blockquote>
  
==Liquids fillers==
+
• ''Iron'' is used as a ‘saddener’ and is used to darken colours.<br /> • ''Copper sulphate'' also darkens but can give shades which are otherwise very difficult to obtain.<br /> • ''Tin'' brightens colours.<br /> • ''Tannic acid'', used traditionally with other mordants, will add brilliancy.<br /> • ''Chrome'' is good for obtaining yellows.<br /> • ''Oxalic acid'' is good for extracting blues from berries.<br /> • ''Cream of Tartar'' is not really a mordant but is used to give a lustre to wool.
  
<div class="booktext">
+
Mordants are often poisonous, and in the dye-house they should be kept on a high shelf out of the reach of children. Always use protective clothing when working with mordants and avoid breathing the fumes.
  
The simplest method is to fill containers from a jug that is calibrated for the correct volume. A funnel can be used to assist filling narrow necked bottles. A simple frame to tilt jars so that the correct filling level is achieved is shown in Figure 6, this will also speed up the filling operation.
+
</blockquote>
  
<center>
+
<br /> The mordant can be added before, during or after the dyeing stage, although most recipes call for mordanting to take place prior to dyeing. It is best to follow the instructions given in the recipe being used or experiment on a sample before carrying out the final dyeing. Later in this brief we will explain how the mordant is mixed and used as part of the dyeing process.
  
[[Image:Food_Packaging_Glass_7.gif]]<br /> Figure 6: Simple frame and jar filling
+
These chemical mordants are usually obtained from specialist suppliers or from chemists. Where this is prohibitive, due to location or cost, natural mordants can be used. There are a number of plants and minerals which will yield a suitable mordant, but their availability will be dependent upon your surroundings. Some common substitutes for a selection of mordants are listed below.<br />
  
</center>
+
<blockquote>
 
 
At a larger scale of production, a filler can be made by fixing taps into a 50 litre stainless steel bucket (Figure 7). Food grade plastic is acceptable for cold filling.
 
 
 
<center>
 
 
 
[[Image:Food_Packaging_Glass_8.gif]]<br /> Figure 7: Bucket with tap
 
 
 
</center>
 
 
 
However, these methods are relatively slow and therefore only suitable for small production rates (eg up to 1000 packs per day). They also give some variation in the filled volume, even with careful training of the operators.
 
  
At higher production rates a piston filler gives a uniform fill-volume and can be adjusted to fill different containers from 25-800 ml. Typical outputs are 15-30 packs per minute.
+
• Some plants, such as mosses and tea, contain a small amount of aluminium. This can be used as a substitute to alum. It is difficult to know, however, how much aluminium will be present and experimentation may be necessary.
  
A different approach is to use a vacuum filler. These are available commercially but can also be made locally. The principle of operation is shown in Figure 8. A venturi pump, obtained from a laboratory supplier, is attached to a water tap to create the vacuum. This then sucks liquid from a product tank into the bottle until it fills to a pre-set level.
+
• Iron water can be used as a substitute to ferrous sulphate. This can be made simply by adding some rusty nails and a cupful of vinegar to a bucket-full of water and allowing the mixture to sit for a couple of weeks.
  
<center>
+
• Oak galls or sumach leaves can be used a substitute to tannic acid.
  
[[Image:Food_Packaging_Glass_9.gif]]<br /> Figure 8: Vacuum filler
+
• Rhubarb leaves contain oxalic acid.
  
</center></div>
+
</blockquote></div>
  
==Sealing==
+
==Natural dyestuffs==
  
 
<div class="booktext">
 
<div class="booktext">
  
Most caps for bottles and jars have a ring of plastic material (sometimes waxed card or cork) which forms a tight seal against the glass. During hot filling and heat processing this plastic softens and beds itself around the glass to make an hermetic seal. However, before this happens there is a risk that small amounts of air can be sucked into a container and cause contamination of the product. The risk of contamination can be reduced by laying a filled container on its side for about 10 minutes to ensure that the seal is perfectly formed.
+
Dyestuffs and dyeing are as old as textiles themselves. Nature provides a wealth of plants which will yield their colour for the purpose of dyeing, many having been used since antiquity. In this section we will look at some of these naturally occurring dyes, their source and the colours they produce. Later in the brief we will look at the application of the dyes to textiles.
 
 
Specific types of equipment are used for sealing the different caps that are used for glass containers.
 
  
For bottles the main types are:<br />
+
Almost any organic material will produce a colour when boiled in a dye-bath, but only certain plants will yield a colour that will act as a dye. The plants given in Table 1 are a selection of plants that have stood the test of time, and are used widely and traditionally by natural dyers. Natural dyes fall into the following categories:<br />
  
 
<blockquote>
 
<blockquote>
  
crown caps<br /> • roll-on-pilfer-proof (ROPP) caps<br /> • snap-on caps<br /> • corks
+
Leaves and stems<br /> • Twigs and prunings<br /> • Flower heads<br /> • Barks<br /> • Roots<br /> • Outer skins, hulls and husks<br /> • Heartwoods and wood shavings<br /> • Berries and seeds<br /> • Lichens<br /> • Insect dyes
  
</blockquote>
+
</blockquote><center>
  
<br /> For jars the main types are:<br />
+
[[Image:Marigold02.gif]]<br /> Figure 2: Marigold
  
<blockquote>
+
</center><div align="left">
  
• twist-on-twist-off (TOTO) lids<br /> • push on lids
+
{| border="1" cellpadding="5"
 +
|- valign="top"
 +
| valign="top" |
 +
Common Name
 +
| valign="top" |
 +
Latin Name
 +
| valign="top" |
 +
Parts Used
 +
| valign="top" |
 +
General Colour Guide
 +
| valign="top" |
 +
Suggested Mordant
 +
|- valign="top"
 +
| valign="top" |
 +
Alder
 +
| valign="top" |
 +
Alnus spp
 +
| valign="top" |
 +
Bark
 +
| valign="top" |
 +
Yellow/brown/black
 +
| valign="top" |
 +
Alum, iron. Copper sulphate
 +
|- valign="top"
 +
| valign="top" |
 +
Alkanet
 +
| valign="top" |
 +
Anchusa tinctoria
 +
| valign="top" |
 +
Root
 +
| valign="top" |
 +
Grey
 +
| valign="top" |
 +
Alum, cream of tartar
 +
|- valign="top"
 +
| valign="top" |
 +
Apple
 +
| valign="top" |
 +
Malus spp
 +
| valign="top" |
 +
Bark
 +
| valign="top" |
 +
Yellow
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Blackberry
 +
| valign="top" |
 +
Rubus spp
 +
| valign="top" |
 +
Berries, young shoots
 +
| valign="top" |
 +
Pink, Purple
 +
| valign="top" |
 +
Alum, tin
 +
|- valign="top"
 +
| valign="top" |
 +
Betel nut
 +
| valign="top" |
 +
Areca catechu
 +
| valign="top" |
 +
Nut
 +
| valign="top" |
 +
Deep pink
 +
|- valign="top"
 +
| valign="top" |
 +
Blackwillow
 +
| valign="top" |
 +
Salix negra
 +
| valign="top" |
 +
Bark
 +
| valign="top" |
 +
Red, brown
 +
| valign="top" |
 +
Iron
 +
|- valign="top"
 +
| valign="top" |
 +
Bloodroot
 +
| valign="top" |
 +
Sanguinaria canadensis
 +
| valign="top" |
 +
Roots
 +
| valign="top" |
 +
Red
 +
| valign="top" |
 +
Alum, tin
 +
|- valign="top"
 +
| valign="top" |
 +
Buckthorn
 +
| valign="top" |
 +
Rhammus cathartica
 +
| valign="top" |
 +
Twigs, berries, bark
 +
| valign="top" |
 +
Yellow, brown
 +
| valign="top" |
 +
Alum, cream of tartar, tin, iron
 +
|- valign="top"
 +
| valign="top" |
 +
Cherry (wild)
 +
| valign="top" |
 +
Prunus spp
 +
| valign="top" |
 +
Bark
 +
| valign="top" |
 +
Pink, yellow, brown
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Dahlia
 +
| valign="top" |
 +
Dahlia spp
 +
| valign="top" |
 +
Petals
 +
| valign="top" |
 +
Yellow bronze
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Dog’s mercury
 +
| valign="top" |
 +
Mercurialis perennis
 +
| valign="top" |
 +
Whole plant
 +
| valign="top" |
 +
Yellow
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Dyer’s broom
 +
| valign="top" |
 +
Genista tinctoria
 +
| valign="top" |
 +
Flowering tops
 +
| valign="top" |
 +
Yellow
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Elder
 +
| valign="top" |
 +
Sambucus negra
 +
| valign="top" |
 +
Leaves, berreis, bark
 +
| valign="top" |
 +
Yellow, grey
 +
| valign="top" |
 +
Iron, alum
 +
|- valign="top"
 +
| valign="top" |
 +
Eucalyptus
 +
| valign="top" |
 +
Eucalyptus
 +
| valign="top" |
 +
Leaves
 +
| valign="top" |
 +
Deep gold, grey
 +
|- valign="top"
 +
| valign="top" |
 +
Fustic
 +
| valign="top" |
 +
Chloropho-ria tinctoria
 +
| valign="top" |
 +
Wood shavings
 +
| valign="top" |
 +
Yellow
 +
|- valign="top"
 +
| valign="top" |
 +
Groundnut
 +
| valign="top" |
 +
Arachis hypogea
 +
| valign="top" |
 +
Kernel skins
 +
| valign="top" |
 +
Purple, brown, pink
 +
| valign="top" |
 +
Copper sulphate, alum
 +
|- valign="top"
 +
| valign="top" |
 +
Henna
 +
| valign="top" |
 +
Lawsonia inermis
 +
| valign="top" |
 +
Leaves
 +
| valign="top" |
 +
Gold
 +
|- valign="top"
 +
| valign="top" |
 +
Hypogymnia lichen
 +
| valign="top" |
 +
Hypogymnia psychodes
 +
| valign="top" |
 +
Whole lichen
 +
| valign="top" |
 +
Gold, brown
 +
|- valign="top"
 +
| valign="top" |
 +
Indigo
 +
| valign="top" |
 +
Indigofera
 +
| valign="top" |
 +
Leaves
 +
| valign="top" |
 +
Blue
 +
| valign="top" |
 +
Not required
 +
|- valign="top"
 +
| valign="top" |
 +
Ivy
 +
| valign="top" |
 +
Hedera helix
 +
| valign="top" |
 +
Berries
 +
| valign="top" |
 +
Yellow, green
 +
| valign="top" |
 +
Alum, tin
 +
|- valign="top"
 +
| valign="top" |
 +
Madder
 +
| valign="top" |
 +
Rubia tinctora
 +
| valign="top" |
 +
Whole plant
 +
| valign="top" |
 +
Orange, red
 +
| valign="top" |
 +
Alum, tin
 +
|- valign="top"
 +
| valign="top" |
 +
Maple
 +
| valign="top" |
 +
Acer spp
 +
| valign="top" |
 +
Bark
 +
| valign="top" |
 +
Tan
 +
| valign="top" |
 +
Copper sulphate
 +
|- valign="top"
 +
| valign="top" |
 +
Marigold
 +
| valign="top" |
 +
Calendual spp
 +
| valign="top" |
 +
Whole plant, flower heads
 +
| valign="top" |
 +
Yellow
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Nettles
 +
| valign="top" |
 +
Urtica dioica
 +
| valign="top" |
 +
Leaves
 +
| valign="top" |
 +
Beige, yellowy greens
 +
| valign="top" |
 +
Alum, copper
 +
|- valign="top"
 +
| valign="top" |
 +
Onion
 +
| valign="top" |
 +
Allium cepa
 +
| valign="top" |
 +
Skins
 +
| valign="top" |
 +
Yellow, orange
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Oak
 +
| valign="top" |
 +
Quercus spp
 +
| valign="top" |
 +
Inner bark
 +
| valign="top" |
 +
Gold, brown
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Ochrolech-ina lichen
 +
| valign="top" |
 +
Ochrolech-ina parella
 +
| valign="top" |
 +
Whole lichen
 +
| valign="top" |
 +
Orange, red (when fermanted in urine then boiled)
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Privet
 +
| valign="top" |
 +
Ligustrum vulgare
 +
| valign="top" |
 +
Leaves, berries
 +
| valign="top" |
 +
Yellow, green, red, purple
 +
| valign="top" |
 +
Alum, tin
 +
|- valign="top"
 +
| valign="top" |
 +
Ragwort
 +
| valign="top" |
 +
Senecio
 +
| valign="top" |
 +
Flowers
 +
| valign="top" |
 +
Deep yellow
 +
|- valign="top"
 +
| valign="top" |
 +
Safflower
 +
| valign="top" |
 +
Carthamus tinctoria
 +
| valign="top" |
 +
Petals
 +
| valign="top" |
 +
Yellow, red
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Sloe-Blackthorn
 +
| valign="top" |
 +
Prunus spinosa
 +
| valign="top" |
 +
Sloe berries, bark
 +
| valign="top" |
 +
Red, pink, brown
 +
| valign="top" |
 +
Alum
 +
|- valign="top"
 +
| valign="top" |
 +
Tea
 +
| valign="top" |
 +
Camelia sinensis
 +
| valign="top" |
 +
Leaves
 +
| valign="top" |
 +
Beige
 +
|- valign="top"
 +
| valign="top" |
 +
Turmeric
 +
| valign="top" |
 +
Circuma longa
 +
| valign="top" |
 +
Root
 +
| valign="top" |
 +
Yellow
 +
|- valign="top"
 +
| valign="top" |
 +
Wild mangosteen
 +
| valign="top" |
 +
Diospyros peregrina
 +
| valign="top" |
 +
Fruit
 +
| valign="top" |
 +
Grey, pink
 +
|- valign="top"
 +
| valign="top" |
 +
Weld (wild mignonette)
 +
| valign="top" |
 +
Reseda luteula
 +
| valign="top" |
 +
Whole plant
 +
| valign="top" |
 +
Olive green
 +
| valign="top" |
 +
Alum, cream of tartar
 +
|- valign="top"
 +
| valign="top" |
 +
Woad
 +
| valign="top" |
 +
Isatis tinctoria
 +
| valign="top" |
 +
Whole plant
 +
| valign="top" |
 +
Blue
 +
| valign="top" |
 +
Lime
 +
|}
  
</blockquote>
+
</div>
  
<br /> All lids and caps should neither affect the product nor be affected by it and they should seal the container for its expected shelf life. This is usually found by testing trial containers with the product to be packaged to make sure that there is no interaction between the pack and the product. Expert advice should also be sought from the packaging suppliers when selecting the type of closure to be used.
+
Table 1. A list of plants commonly used for preparing dyes.
  
</div>
+
The choice of mordant for a particular plant is dependant upon the material with which it will be used. It is necessary to check a recipe before using a plant, or one can experiment to see what effect a mordant has for a particular application.
  
==Bottles==
+
It is recommended that plants be grown specifically for the purpose of dyeing. Harvesting plants from the wild on a non-sustainable basis can endanger the survival of the plant. Many lichens are registered as protected organisms and it is illegal to gather them from the wild. One source of lichen is from timber mills where logged trees are being processed, but ask first!
  
<div class="booktext">
+
<center>
  
Crown caps are commonly used for beer bottles and fruit juices. Hand-operated equipment is available in a number of sizes from a simple former that is placed over the cap and hit with a mallet, to the hand-held lever type shown in Figure 9 and table mounted model shown in Figure 10.
+
[[Image:Groundnuts03.gif]]<br /> Figure 3: Groundnuts
  
<center>
+
</center></div>
  
[[Image:Food_Packaging_Glass_10.gif]]<br /> Figure 9: Hand held bottle capping
+
==Testing dyes==
  
</center><center>
+
<div class="booktext">
  
[[Image:Food_Packaging_Glass_11.gif]]<br /> Figure 10: Table mounted bottle capping
+
It is always useful and interesting to test the dye which is to be used on a sample of the yarn or fabric to be dyed. The outcome will depend on the fabric, the mordant that has been used and dye that has have been chosen. Testing is best carried out on a series of marked (for identification) samples, which have been mordanted with a number of different mordants. Tests can be carried out for light, water and washing fastness using simple standard test methods. Box 1 shows a simple test for washing fastness. Similar tests exists for water and light fastness (and are given in detail in the same book).
  
</center>
+
'''Box 1'''
  
Roll-on-pilfer-proof (ROPP) caps are fitted by placing a blank cap on the bottle and then pressing the metal into the screw thread of the glass. Finally, a ring of perforated metal is formed at the base of the cap that shows evidence of tampering or pilfering. Hand operated ROPP machines can be constructed locally (Figure 11) and small motorised version are available commercially (Figure 12). A simpler cap which does not incorporate the pilferproof feature is known as a 'Roll-on (RO) cap and this can be fitted by similar types of equipment.
+
<div align="left">
  
<center>
+
{| border="1" cellpadding="5"
 +
|- valign="top"
 +
| valign="top" |
 +
''Test method for fastness to washing''
  
[[Image:Food_Packaging_Glass_12.gif]]<br /> Figure 11: Hand operated ROPP machine
+
To test for fastness follow these steps:<br />
  
</center><center>
+
<blockquote>
  
[[Image:Food_Packaging_Glass_13.gif]]<br /> Figure 12: Motorised ROPP machine
+
1. Take two pieces of fabric about 5cm by 5cm, one of which is undyed cotton and the other undyed wool. Stitch them together along one side.
  
</center>
+
2. Take some sample strips of the dyed yarn and spread them evenly between the two pieces of cloth so that they overlap both sides. If dyed fibre is being tested a combed sample can be used in place of the yarn.
  
Plastic snap-on caps are fitted over the neck of the bottle and sealed by a capping machine (Figure 13).
+
3. Sew around all four sides of the cloth so that the yarn is held in place.
  
Corks are mostly used to seal wine bottles and hand operated corkers which both squeeze the cork and insert it into the bottle are available (Figure 14). Corks are first wetted to make them slip more easily into the bottle and they then expand to give an airtight, waterproof seal. As corks may be contaminated by microorganisms, it is important that the soaking water contains either a few drops of bleach per litre or sodium metabisulphite at approximately one teaspoonful per 5 litres'''.'''
+
4. Prepare a similar specimen with dyed materials that has satisfactory properties and place them in two jars with screw lids containing a solution of 5gm per litre soap or detergent solution at 30oC.
  
<center>
+
5. Agitate the two jars gently for 30mins, then remove the fabrics and wash them gently in clean water for 5mins. Open the stitching and separate the pieces to dry in air.
  
[[Image:Food_Packaging_Glass_14.gif]]<br /> Figure 13: Capping machine
+
</blockquote>
  
</center><center>
+
<br /> Examination:<br />
  
[[Image:Food_Packaging_Glass_15.gif]]<br /> Figure 14: Hand operated corking machine
+
<blockquote>
  
</center></div>
+
6. Place the dyed yarn next to a sample of the same material which has not been tested, and compare the change which has taken place. Compare also with the control sample with satisfactory properties. If the dyeing being tested shows equal or less change than the satisfactory sample, then it is as good as the satisfactory sample.
  
==Jars==
+
7. Place the wool and cotton cloths next to samples of the same material which have not been tested and compare them with the cloths that have been tested with a satisfactory dyeing. Equal or less staining shows equal or better fastness.
  
<div class="booktext">
+
</blockquote>
 +
|}
  
Push-on lids are still used for sealing jars (Figure 15) although these are increasingly being replaced by twist-on-twist-off (TOTO) lids. Small equipment is available for each of these types of closure.
+
</div><blockquote>
  
<center>
+
Source: Dyeing and printing: a handbook, ITDG Publishing
  
[[Image:Food_Packaging_Glass_16.gif]]<br /> Figure 15: Jar sealer
+
</blockquote>
  
</center><center>
+
<br /> Processing of the plant can take one of many forms, but usually takes the form of soaking or boiling the plant to extract the dye. Some plants, such as indigo, need special preparation for use. Some plants will need boiling to extract their dye while others can merely be soaked for extended periods. Detailed instructions for processing of a wide variety of plants can be found in some of the texts given in the reference chapter at the end of this document.
  
[[Image:Food_Packaging_Glass_17.gif]]<br /> Figure 16: Bottle cooling equipment
+
</div>
  
</center></div>
+
==The process of dyeing==
  
==Processing==
 
  
<div class="booktext">
+
'''Application of the Dye'''
  
Some products are heat processed after packing into glass containers. They should be heated and cooled gently in order to avoid breaking the glass. One method of controlled cooling of containers after processing is shown in Figure (16). Cold water enters at the deep end of the trough and overflows at the shallow end. Hot bottles are placed in at the shallow end and roll down to the deep end. The temperature is cool at the deep end and gets hotter along the trough, so minimising the shock to the hot containers.
+
Dyeing can be carried out at any of the following stages in the textile manufacturing stage:<br />
  
</div>
+
<blockquote>
  
==Labelling==
+
• The fibres can be dyed before they are spun. ''Fibre dyeing'' provides a deep penetration of the dye into the fibre, giving even colour and excellent colour-fastness.
  
<div class="booktext">
+
• The yarn can be dyed after spinning but before the product is woven or otherwise fabricated. This is called ''package dyeing''.
  
Paper labels are the most common type used on glass containers. They can be plain paper that is glued onto the glass or alternatively self-adhesive types. Figure 17 shows a simple frame which can be used to hold plain labels, wipe glue over top of label in stack, roll jar along guide rail over label, roll and press jar and label into rubber mat. Small labelling machines (Figure 18) can be used to apply strips of glue to labels. A typical powered labeller has an output of about 40 labels per minute.
+
• Before the fabric is finished, it can be dyed in lengths (''piece dyeing'').This process allows manufacturers the opportunity to produce fabrics in their natural colours, and then dye them to order.
  
<center>
+
• In ''cross-dyeing'', fabrics of two or more fibres can be dyed so that each fibre accepts a different dyestuff and becomes a different colour, through the use of appropriate dyestuffs for each fibre.
  
[[Image:Food_Packaging_Glass_18.gif]]<br /> Figure 17: Labelling table
+
</blockquote>
  
</center><center>
+
<br /> It is essential for the correct identification of the fibre or other fabric to be made before dyeing commences.
  
[[Image:Food_Packaging_Glass_19.gif]]<br /> Figure 18: Small labelling machine
+
'''Methods of dyeing'''
  
</center>
+
There are a number of methods of applying dye to a fabric. Although the most common method used for applying natural dyes is the vat method, there are techniques which have been developed to allow patterns to be incorporated during the dying process. It is worth bearing in mind that using natural dyes is a complex art and the skills required for using natural dyes are learned over many years. Don’t be put off if you don’t get the desired results at the first attempt!
  
Water soluble glues such as starch or cellulose based glues are best if containers are returnable, so that labels can be easily removed. However, these glues may loose adhesion in humid climates. Non water-soluble glues, based on plastic polymers, are available and advice on the correct type should be sought from the suppliers.
+
'''Vat Dyeing'''
  
Self-adhesive labels can be bought, fixed to a backing (or 'release') paper in rolls or sheets. They can be applied by hand, by small hand held machines or by powered labellers. The type shown in Figure 19 can apply 30-40 labels per minute.
+
In the simplest form of dyeing a textile material is immersed in dye and gradually brought to the boil. Alternatively the fibre is allowed to sit and soak for several hours or days. During this period, agitation is necessary to allow full penetration of the textile by the dyestuff. Depending on the type of fabric and dyestuff used, certain salts or acids may be added to assist absorption of the dye.
  
 
<center>
 
<center>
  
[[Image:Food_Packaging_Glass_20.gif]]<br /> Figure 19: Powered labelling machine
+
[[Image:Groundnuts03.gif]]
  
</center></div>
+
</center>
  
==Quality control==
+
The principal difficulty in dyeing mixed yarns and fabrics is to achieve the same colour in both fibres. Cotton fibres may, for instance, absorb dyes rapidly, while the wool fibres will have to be boiled over an extended period to reach the same depth of shade. This could lead to significant damage to the material. In this case a chemical compound would need to be used to restrain the rate at which the cotton fibre takes up the dyestuff.
  
<div class="booktext">
+
The amount of dyestuff which is used is usually given in the recipe. It is usually quoted as a percentage weight of the fabric to be dyed. Box 2 demonstrates a typical, simple recipe for dyeing using natural dyestuff, in this case onion skins.
  
This should be seen as a method of saving money and ensuring good quality products and not as an unnecessary expense. The time and effort put into quality control should therefore be related to the types of problems experienced or expected. For example, glass splinters in a food are very serious and every effort should be made to prevent them, whereas a misaligned label may not look attractive but will not harm the customers.
+
Box 2
  
Faults can be classified as:
+
<div align="left">
  
'''Critical''' likely to harm the customer or operator or make the food unsafe (eg glass splinters)
+
{| border="1" cellpadding="5"
 +
|- valign="top"
 +
| valign="top" |
 +
'''Recipe for dyeing wool with onion skins'''
  
'''Major''' likely to make the package unsuitable for use in the process or result in a serious loss of money to the business (eg non-vertical bottles that would break in a filling machine)
+
Fabric: applicable to wool or other animal (protein) fibres.
  
'''Minor''' likely to affect the appearance of a pack (eg ink smudges on the label)
+
You will need:<br />
  
Critical faults should always be checked for, whereas others may be examined, if they are causing problems.
+
<blockquote>
  
For glass containers the critical faults are broken, cracked, or chipped glass, strands of glass stretched across the inside of new packs, or bubbles in the glass that make it very thin in places. Major faults are variations in the size and shape of containers and minor faults include uneven surfaces, off colours in the glass, rough mould lines and faults with the label.
+
• 100 grams of natural wool<br /> • 30 grams of onion skins (use only the dry, brown, outer skins)<br /> • 8 grams of alum (the mordant)<br /> • 7 grams cream of tartar (the assistant)<br /> • Some liquid detergent (the scouring agent)<br /> • A water supply*
  
One further quality control measure that is important with glass containers is to check variations in the weight of jars and bottles as these variations will affect the fill-weight. Random samples should be taken from the delivery of containers (eg 1 in 50 containers) and weighed. The heaviest pack should then be used to calculate the final filled weight required.
+
</blockquote>
  
Quality control needs trained staff, an established procedure and some equipment and facilities. Staff are the most important and all operators should be trained to look out for faults in the product or package. One staff member should have responsibility for checking the packaging.
+
<br /> If a larger quantity of wool is to be dyed, increase the quantities proportionally.
  
All glass jars and bottles should be checked for critical faults and if second-hand, checked for contamination before washing. Other quality control checks include:<br />
+
Weigh the wool. All weights given are relative to the dry weight of the wool. Skeins of wool are tied loosely in several places to prevent tangling. In this case the recipe calls for 30% dyestuff i.e. the weight of the dyestuff is 30% that of the fabric to be dyed.
  
<blockquote>
+
The wool should be scoured. This means getting the wool completely clean. For this the wool is soaked overnight in a liquid detergent solution. Rinse the wool well and gently squeeze out the excess water. Use lukewarm water and avoid sudden changes in the temperature of the water which cause the wool to felt or mat.
  
the filled weight (to ensure that the net weight is the same as that declared on the label)
+
Next the skein will be mordanted. Dissolve the alum and cream of tartar in a little hot water and then add this solution to cool water in the mordant pan. Immerse the wetted yarn and then place the pan on the heat source. Slowly raise the temperature to 82oC (180oF) and simmer for 45 minutes. Leave to cool, then remove the wool and rinse well.
  
the appearance of the pack
+
To prepare the dyebath, place the onion skins in the dyepan and cover them with water. Slowly heat the dyebath to boiling point. Simmer for about 45 minutes by which time all the colour should have been extracted from the onion skins. Remove from the heat, allow to cool and then strain of the liquid form the skins.
  
• a proper seal formed by the cap
+
The dyeing process is then carried out. The mordanted, thoroughly wetted fabric is placed into the now cool dyebath. Replace the heat under the dyebath, bring the temperature up to boiling point and then immediately reduce the heat to 82oC (180oF) and simmer for 45 minutes or until the wool is the required colour. Remember that wool is darker when wet than when dry. Remove the wool from the dyebath if no further uptake of dye is required, or allow the fabric to cool with the liquid in the dyebath. Do not cool quickly with cold water.
  
the presence and position of the correct label.
+
When the skein of wool is cool, rinse it thoroughly in several changes of water until the water is clear, then wash the skein of wool in soapy water, rinse and allow to dry.
  
</blockquote>
+
<nowiki>*Ordinary tap water is normally suitable for dyeing. If ‘soft’ water is called for then rain water can be used. A plentiful supply of fresh water is always required when dyeing.</nowiki>
 +
|}
  
<br /> Filled weight can be checked using a scale that has the package plus a known weight on one side and samples of filled product placed on the other side (Figure 20). The number of samples required to be checked depends on the amount of food produced and the method of filling. In general, hand filling is more variable than machines and therefore more samples are required. As a rough guide, one in every twenty packs should be checked.
+
</div><blockquote>
  
<center>
+
'''Source: The Craft of Natural Dyeing, Jenny Dean'''
  
[[Image:Food_Packaging_Glass_21_a.gif]]<br /> Figure 20: Scales
+
</blockquote>
  
</center></div>
+
<br />'''Batik'''
  
==Collation for transport/distribution==
+
Batik is a starch resist-dyeing process, developed on the Island of Java in modern-day Indonesia. Colour is prevented from reaching certain areas of a fabric by covering these areas with molten wax. The fabric is starched prior to the design being drawn upon it. The wax is applied with a type of cup with a fine pouring spout'','' usually made of copper. The technique has been developed to a high art form in Indonesia from where it is exported to many parts of the world. Batik paintings, as well as sarongs and lengths of fabric, are produced. When the fabric is dyed, all waxed areas resist the dyestuff. The wax is then removed by placing the fabric in boiling water. For patterns with many colours the same procedure is repeated until the full design is completed.
  
<div class="booktext">
+
'''Tie-dyeing'''
  
Once the containers have been filled, sealed and labelled they are grouped together to make transport and handling easier. Cardboard boxes are most commonly used and these can be bought or made up on site. A paper label can be used to cover existing printing on reused boxes and also advertise the product during distribution.
+
Tie-dyeing is another popular artisanal dyeing technique. In this resist-dyeing process, waxed thread is tightly tied around the areas chosen to resist the coloured dyestuff, and the fabric is dipped into the dye. The waxed thread is then removed and the fabric dried. This process can be repeated for each colour to be added.
 
 
The required size of a box can be found by placing together the containers to be packed, together with dividers, and measuring the size to find the minimum internal dimensions (see Figure 21).
 
  
 
<center>
 
<center>
  
[[Image:p08b.gif]]<br /> Figure 21: Sizing
+
[[Image:p009a.gif]]<br /> Wild Mangosteen
  
 
</center>
 
</center>
  
Newer methods of collating containers include shrinkwrap or stretchwrap films which hold the bottles or jars together on card trays (Figures 22 & 23).
+
'''Obtaining unusual colours'''
 +
 
 +
Colours other than those obtained by simply using a single dye, can be obtained by mixing dyes or dyeing a fabric more than once in different dyebaths. The colour triangle on the next page is a useful tool in determining the colours needed to produce a required shade.
  
 
<center>
 
<center>
  
[[Image:p08c.gif]]<br /> Figure 22: Wrapping machine
+
[[Image:p009b.gif]]
 
 
</center><center>
 
 
 
[[Image:p08d.gif]]<br /> Figure 23 Wrapping boxes for transport
 
  
 
</center></div>
 
</center></div>
  
==Equipment suppliers==
+
==References and further reading==
  
 
<div class="booktext">
 
<div class="booktext">
  
'''Bottle/cap sealers'''
+
Foulds, John, '''''<u>Dyeing and printing: a handbook</u>''''', ITDG Publishing, 1989. The text and line drawings describe chemical dyeing and printing techniques as they apply to small-scale operations. 128pp.
  
Rajan Universal Exports (MFRS) P Limited<br /> Raj Buildings 162<br /> Linghi<br /> Chetty Street<br /> P Bag No 250<br /> Madras 600 001<br /> India<br /> Tel: +91 (0)44 2534 1711<br /> Fax: +91 (0)44 2534 2323
+
Sayadda R. Ghuznavi, '''''Rangeen - Natural dyes of Bangladesh,''''' Vegetable Dye Research and Development Society, Bangladesh, 1987. This interesting book gives listings of indigenous Bangladeshi plants as well as recipes for their use.
  
Narangs Corporation<br /> 25/90 Connaught Place<br /> Below Madras Hotel<br /> New Delhi 110 001<br /> India<br /> Tel: +91 (0)11 2336 3547<br /> Fax:+91 (0)11 2374 6705
+
Dalby, Gill and Dean, Jenny, '''''Natural Dyes in Luapula Province (Zambia): Evaluation of Potential for Production, Use and Export.''''' Working Paper 22, Development Technology Unit, University of Warwick, Coventry CV4 7AL, UK. 1988.
  
M.M.M.Buxabhoy & Co. 140 Sarang Street<br /> 1st.Floor<br /> Near Crawford Market<br /> Mumbai<br /> India<br /> Telephone: +91 (0)22 2344 2902<br /> Fax: +91 (0)22 2345 2532<br /> Email: [mailto:yusufs@glasbm01.vsnl.net.in yusufs@glasbm01.vsnl.net.in]<br /> Manual heat sealing machine used for sealing<br /> plugs of plastic containers, bottles, jars<br /> and jerry cans.
+
Dean, Jenny: '''''The Craft Of Natural Dyeing,''''' Search Press, 1994 This guide tells how to grow and find, harvest, and use all NON-TOXIC dyes in nature. It is excellent for children. She lists dyestuffs that provide a full spectrum of colours and explains how to test plant dyestuffs for colour potential. 64 pgs, 30 colour photos, 16 illustrated charts, paperback.
  
'''Liquid Filling Equipment'''
+
Cowan, Wavell: '''''Operating A Business In The Small Business Space.''''' A must for anyone who contemplates starting a small business. Xeroxed, spiral bound, non-profit 67 pp.
  
Geeta Food Engineering Plot No. C-7/1 TTC Area<br /> Pawana MIDC<br /> Thane Belapur Road<br /> Behind Savita Chemicals Ltd.<br /> Navi Mumbai - 400 705<br /> India<br /> Tel: +91 (0)22 2782 6626/766 2098<br /> Fax: +91 (0)22 2782 6337<br /> Bottle Washing and Filling Machine
+
McRae, Bobbie: '''''Colors From Nature''<nowiki>:</nowiki>''' Growing, Collecting, and Using Natural Dyes How to grow dye plants, recognise and collect wild plants, and even find dyes in the produce department of the grocery store. Step-by-step instructions for over a dozen naturally dyed crafts projects. 168 pp.
  
Autopack Machines PVT LTD 101-C, Poonam Chambers<br /> 'A' Wing, 1st Floor<br /> Dr. Annie Besant Road<br /> Worli<br /> Mumbai - 400 018<br /> India<br /> Tel: +91 (0)22 2493 4406/2497 4800/2492 4806<br /> Fax: +91 (0)22 2496 4926<br /> E-mail: [mailto:autopack@bom3.vsnl.net.in autopack@bom3.vsnl.net.in]<br /> Pneumatic liquid filler suitable for filling any food products in liquid form into bottles. No electric power is required. Up to 20 fills/minute
+
</div>
  
Dairy Udyog C-230, Ghatkopar Industrial Estate<br /> L.B.S. Marg<br /> Ghatkopar (West)<br /> Bombay - 400 086<br /> India<br /> Tel: +91 (0)22 2517 1636 / 517 1960<br /> Fax: +91 (0)22 2517 0878<br /> Email: [mailto:jipun@vsnl.com jipun@vsnl.com]<br /> Sealing and Filling Machines: Semi automatic machine for packing liquids such as milk, oil, ghee etc. in pillow packs. Capacity: 300 pack/hour Power: Electric
+
==Useful addresses==
  
Mark Industries PVT Ltd 348/1 Dilu Road<br /> Mokbazar<br /> Dhaka-1000<br /> Bangladesh<br /> Tel: +880 2 9331778 / 835629 / 835578<br /> Fax: +880 2 841049<br /> E-mail: [mailto:markind@citechco.net markind@citechco.net]<br /> Manually powered Juice filling machine.
+
<div class="booktext">
 
 
'''Bottle washing Equipment'''
 
 
 
Gardners Corporation 6 Doctors Lane<br /> Near Gole Market<br /> PO Box 299<br /> New Delhi - 110001<br /> India<br /> Tel: +91 (0)11 2334 4287 / 336 3640<br /> Fax: +91 (0)11 2371 7179<br /> Bottle Washing Machine. This machine has 2 brushes and a drive motor.<br /> Power: Electric.
 
  
Dairy Udyog<br /> Ghatkopar Industrial Estate<br /> LBS Marge, Ghatkopar,<br /> Mumbai 400 086, India<br /> Tel: +91 (0)22 2517 1636/ 2517 1960<br /> Fax: +91 (0)22 2517 0878<br /> Bottle brushes
+
Earth Guild, 33 Haywood Street Asheville NC 28801,<br /> USA<br /> Tel: +1 800 327 8448<br /> Fax: +1 (704) 255 8593<br /> E-mail: [mailto:inform@earthguild.com inform@earthguild.com] or [mailto:catalog@earthguild.com catalog@earthguild.com]<br /> Suppliers of natural dyes and dyeing equipment.
  
'''Labelling machines'''
+
Vegetable Dye Research and Development Society,<br /> P.O.Box 268,<br /> Dhaka,<br /> Bangladesh.<br /> Carry out R&D and publish books on Natural Dyeing
  
Rank and Company A-95/3<br /> Wazirpur Industrial Estate<br /> Delhi - 110 052<br /> India<br /> Telephone: +91 (0)11 2745 6101/2/3/4<br /> Fax: +91 (0)11 2723 4126 / 2743 3905<br /> Email: [mailto:rank@poboxes.com rank@poboxes.com]<br /> Label Gumming Machine Used for pasting gum on labels.
+
The Crafts Council,<br /> 1 Oxenden Street,<br /> London SW1Y 4AT.<br /> United Kingdom<br /> Tel: +44 (0)20 7930 4811
  
Narangs Corporation<br /> 25/90 Connaught Place<br /> Below Madras Hotel<br /> New Delhi 110 001<br /> India<br /> Tel: 91 (0)11 2336 3547<br /> Fax: 91 (0)11 2374 6705<br /> Labelling Gumming Machines<br /> This hand operated label gumming machine is suitable for labels of up to 15cm width. Power: Manual
+
Khadi and Village Industries Commission,<br /> Irla, Vile Parle,<br /> Bombay 400056,<br /> India
  
Bhavani Sales Corporation Plot No.2/1<br /> Phase II<br /> GIDC<br /> Vatva<br /> Ahmedabad - 382 445<br /> India<br /> Tel: +91 (0) 79 2583 1346 / 2589 3253<br /> Fax: +91 (0)79 2583 5885 / 2583 1346<br /> Email: [mailto:labeling@ad1.vsnl.net.in labeling@ad1.vsnl.net.in]<br /> Semi automatic labelling machine suitable for all types of round containers, jars, tins, cans and bottles. Capacity: 30-40 containers/minute
+
Society of Dyers and Colourists,<br /> PO Box 244, Perkin House,<br /> 82 Graton Road,<br /> Bradford BD1 2JB,<br /> United Kingdom<br /> Produce a Colour Index of all known natural and manufactured dyes, but it is very expensive.
  
 
</div>
 
</div>
  
==Acknowledgements==
+
==Useful internet addresses==
  
 
<div class="booktext">
 
<div class="booktext">
  
Some of the diagrams and text used in this technical brief come from a variety of sources. We would there like to thank the following for allowing us to reproduce: TOOL, ILO, and PRODEC.
+
http://www.earthguild.com/products/Dyes/dye.htm Homepage of Earth Guild (see addresses section above).
  
</div>
+
http://www.slonet.org/~crowland/index.html Carol Todd’s Natural Dyeing Homepage. Sells books and electronic database of plants and natural dyes.
  
==References and further reading==
+
http://www.hillcreekfiberstudio.com/Workshops.html Hillcreek Fibre Studio. Runs workshops on weaving and natural dyeing. Based in the USA.
  
<div class="booktext">
+
There are many recipes for natural dyeing given on the Internet. Enter a search on ‘Natural dyeing’ and this will yield a wealth of recipes, suggestions and ideas for the novice (and experienced) dyer.
 
 
''Bottle and Jar Cooling Systems'', Practical Action Technical Brief
 
 
 
''Bottle washing and Steam Sterilising'', Practical Action Technical Brief
 
 
 
''Packaging Materials for Food'', Practical Action Technical Brief
 
 
 
''Small-scale Food Processing: A guide to appropriate equipment'' Edited by Peter Fellows & Ann Hampton, ITDG Publishing/ CTA 1992
 
 
 
''Appropriate Food Packaging'' by Peter Fellows & Barry Axtell, ILO/TOOL 1993
 
 
 
''Packaging'', ''Food Cycle Technology Source Book'', ITDG Publishing/ UNIFEM 1996
 
 
 
''Small-scale Food Processing: A Directory of Equipment and Methods'' by Sue Azam-Ali ITDG Publishing, 2003<br />
 
 
 
</div>
 

Revision as of 16:06, 27 August 2006

Natural Dyeing of Textiles - Technical Brief

Introduction

Dyeing is an ancient art which predates written records. It was practised during the Bronze age in Europe. Primitive dyeing techniques included sticking plants to fabric or rubbing crushed pigments into cloth. The methods became more sophisticated with time and techniques using natural dyes from crushed fruits, berries and other plants, which were boiled into the fabric and gave light and water fastness (resistance), were developed.

Some of the well known ancient dyes include madder, a red dye made from the roots of the Rubia tinctorum, blue indigo from the leaves of Indigofera tinctoria, yellow from the stigmas of the saffron plant, and dogwood, an extract of pulp of the dogwood tree. The first use of the blue dye, woad, beloved by the Ancient Britons, may have originated in Palestine where it was found growing wild. The most famous and highly prized colour through the age was Tyrian purple, noted in the Bible, a dye obtained from the spiny dye-murex shellfish. The Phoenicians prepared it until the seventh century, when Arab conquerors destroyed their dyeing installations in the Levant. A bright red called cochineal was obtained from an insect native to Mexico. All these produced high-quality dark colours. Until the mid-19th century all dyestuffs were made from natural materials, mainly vegetable and animal matter.

Today, dyeing is a complex, specialised science. Nearly all dyestuffs are now produced from synthetic compounds. This means that costs have been greatly reduced and certain application and wear characteristics have been greatly enhanced. But many practitioners of the craft of natural dying (i.e. using naturally occurring sources of dye) maintain that natural dyes have a far superior aesthetic quality which is much more pleasing to the eye. On the other hand, many commercial practitioners feel that natural dyes are non-viable on grounds of both quality and economics. In the West, natural dyeing is now practised only as a handcraft, synthetic dyes being used in all commercial applications. Some craft spinners, weavers, and knitters use natural dyes as a particular feature of their work.

Indigo01.gif
Figure 1: Indigo

In many of the world’s developing countries, however, natural dyes can offer not only a rich and varied source of dyestuff, but also the possibility of an income through sustainable harvest and sale of these dye plants. Many dyes are available from tree waste or can be easily grown in market gardens. In areas where synthetic dyes, mordants (fixatives) and other additives are imported and therefore relatively expensive, natural dyes can offer an attractive alternative.

The knowledge required for sourcing and extracting such dyes and mordants is, however, often not available as extensive research work is required to identify suitable plants, minerals, etc. In Zambia for example, there is a wealth of plants available for producing natural dyes, but due to lack of knowledge of the processes involved in harvesting and processing the plants, little use is made of this natural resource. In some countries, such as India, Nigeria and Liberia, where this research has been carried out, or where there exists a tradition of natural dyeing, natural dyes and mordants are used widely.

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Types of textiles suitable for dying

Natural dyes can be used on most types of material or fibre but the level of success in terms of fastness and clarity of colour varies considerably. Users of natural dyes, however, tend to also use natural fibres, and so we will look in more detail at this group. Natural fibres come mainly from two distinct origins, animal origin or vegetable origin. Fibres from an animal origin include wool, silk, mohair and alpaca, as well as some others which are less well known. All animal fibres are based on proteins. Natural dyes have a strong affinity to fibres of animal origin, especially wool, silk and mohair and the results with these fibres are usually good. Fibres of plant origin include cotton, flax or linen, ramie, jute, hemp and many others. Plant fibres have cellulose as their basic ingredient. Natural dyeing of certain plant based textiles can be less successful than their animal equivalent. Different mordanting techniques are called for with each category. When a blend of fibre of both animal and plant origin is being dyed, then a recipe should be chosen which will accentuate the fibre which is required to be dominant.

Equipment needed for home dyeing and very small-scale commercial dyeing

Most equipment needed for dyeing fabrics at home, or at the very small-scale commercial level, can be found in almost any market place throughout the world. The following is a list of the equipment requirements and a brief explanation of their use.

Heat source. This can be any type of cooking stove; gas, wood, kerosene, charcoal, electricity. This is used for heating the liquid used during mordanting and dyeing.

Pestle and mortar. Used for milling the natural dye or minerals, where this is called for.

Mordanting and dyeing pans. Stainless steel or enamel pans are the most suitable for dyeing. The size of pan depends upon the quantities of fabric that will be dyed. Do not use pans made from copper, aluminium or iron, unless absolutely necessary, as these metals have properties which can change the colour of the dye.

tirring rods. Stainless steel or glass rods are best as they can be cleaned and used for different colour dyes. If wooden stirring rods are used then there should be a different spoon for each colour.

Thermometer. This is used to measure the temperature of the liquid during mordanting and dyeing. A long thermometer (to reach the liquid at the bottom of the pan) is preferred, with a range of 0 - 100oC (32 - 210oF).

Measuring jugs. These are used to measure the quantities of liquid called for in the recipe. Sometimes precise quantities are called for.

Storage containers. Used for storing the dyestuffs and mordants. Large glass and plastic jars are ideal. Some mordants and dyes are sensitive to light and should therefore be stored in sealed light-proof containers.

Plastic bowls and buckets. A variety of plastic bowls or buckets of varying sizes are useful when wetting or rinsing fabrics.

Strainer. Used for straining the liquid off the dyestuff in the dyebath.

Weighing scales. Used for obtaining the correct quantities as specified in the recipe. A scales with metric and imperial measurement is useful as conversions from one system to the other are not then needed.

Protective equipment. Gloves for holding hot pans will prevent burns. An apron will protect your clothing. Rubber gloves will prevent skin irritation caused by mordants, and will also prevent you from dyeing your hands. A face mask can cut down the amount of fumes or powder inhaled during the dyeing process.

Mordants

Few natural dyes are colour-fast with fibres. Mordants are substances which are used to fix a dye to the fibres. They also improve the take-up quality of the fabric and help improve colour and light-fastness. The term is derived from the Latin mordere, to bite. Some natural dyes, indigo for example, will fix without the aid of a mordant; these dyes are known as ‘substantive dyes’. Others dyes, such as madder and weld, have a limited fastness and the colour will fade with washing and exposure to light.

Traditionally, mordants were found in nature. Wood ash or stale urine may have been used as an alkali mordant, and acids could be found in acidic fruits or rhubarb leaves (which contain oxalic acid), for example. Nowadays most natural dyers use chemical mordants such as alum, copper sulphate, iron or chrome (there are concerns, however about the toxic nature of chrome and some practitioners recommend that it is not used).

Mordants are prepared in solution, often with the addition of an ‘assistant’ which improves the fixing of the mordant to the yarn or fibre. The most commonly used mordant is alum, which is usually used with cream of tartar as an additive or assistant. Other mordants are:

• Iron (ferrous sulphate)
• Tin (stannous chloride)
• Chrome (bichromate of potash)
• Copper sulphate
• Tannic acid
• Oxalic acid


Using a different mordant with the same dyestuff can produce different shades, for example;

Iron is used as a ‘saddener’ and is used to darken colours.
Copper sulphate also darkens but can give shades which are otherwise very difficult to obtain.
Tin brightens colours.
Tannic acid, used traditionally with other mordants, will add brilliancy.
Chrome is good for obtaining yellows.
Oxalic acid is good for extracting blues from berries.
Cream of Tartar is not really a mordant but is used to give a lustre to wool.

Mordants are often poisonous, and in the dye-house they should be kept on a high shelf out of the reach of children. Always use protective clothing when working with mordants and avoid breathing the fumes.


The mordant can be added before, during or after the dyeing stage, although most recipes call for mordanting to take place prior to dyeing. It is best to follow the instructions given in the recipe being used or experiment on a sample before carrying out the final dyeing. Later in this brief we will explain how the mordant is mixed and used as part of the dyeing process.

These chemical mordants are usually obtained from specialist suppliers or from chemists. Where this is prohibitive, due to location or cost, natural mordants can be used. There are a number of plants and minerals which will yield a suitable mordant, but their availability will be dependent upon your surroundings. Some common substitutes for a selection of mordants are listed below.

• Some plants, such as mosses and tea, contain a small amount of aluminium. This can be used as a substitute to alum. It is difficult to know, however, how much aluminium will be present and experimentation may be necessary.

• Iron water can be used as a substitute to ferrous sulphate. This can be made simply by adding some rusty nails and a cupful of vinegar to a bucket-full of water and allowing the mixture to sit for a couple of weeks.

• Oak galls or sumach leaves can be used a substitute to tannic acid.

• Rhubarb leaves contain oxalic acid.

Natural dyestuffs

Dyestuffs and dyeing are as old as textiles themselves. Nature provides a wealth of plants which will yield their colour for the purpose of dyeing, many having been used since antiquity. In this section we will look at some of these naturally occurring dyes, their source and the colours they produce. Later in the brief we will look at the application of the dyes to textiles.

Almost any organic material will produce a colour when boiled in a dye-bath, but only certain plants will yield a colour that will act as a dye. The plants given in Table 1 are a selection of plants that have stood the test of time, and are used widely and traditionally by natural dyers. Natural dyes fall into the following categories:

• Leaves and stems
• Twigs and prunings
• Flower heads
• Barks
• Roots
• Outer skins, hulls and husks
• Heartwoods and wood shavings
• Berries and seeds
• Lichens
• Insect dyes

Marigold02.gif
Figure 2: Marigold

Common Name

Latin Name

Parts Used

General Colour Guide

Suggested Mordant

Alder

Alnus spp

Bark

Yellow/brown/black

Alum, iron. Copper sulphate

Alkanet

Anchusa tinctoria

Root

Grey

Alum, cream of tartar

Apple

Malus spp

Bark

Yellow

Alum

Blackberry

Rubus spp

Berries, young shoots

Pink, Purple

Alum, tin

Betel nut

Areca catechu

Nut

Deep pink

Blackwillow

Salix negra

Bark

Red, brown

Iron

Bloodroot

Sanguinaria canadensis

Roots

Red

Alum, tin

Buckthorn

Rhammus cathartica

Twigs, berries, bark

Yellow, brown

Alum, cream of tartar, tin, iron

Cherry (wild)

Prunus spp

Bark

Pink, yellow, brown

Alum

Dahlia

Dahlia spp

Petals

Yellow bronze

Alum

Dog’s mercury

Mercurialis perennis

Whole plant

Yellow

Alum

Dyer’s broom

Genista tinctoria

Flowering tops

Yellow

Alum

Elder

Sambucus negra

Leaves, berreis, bark

Yellow, grey

Iron, alum

Eucalyptus

Eucalyptus

Leaves

Deep gold, grey

Fustic

Chloropho-ria tinctoria

Wood shavings

Yellow

Groundnut

Arachis hypogea

Kernel skins

Purple, brown, pink

Copper sulphate, alum

Henna

Lawsonia inermis

Leaves

Gold

Hypogymnia lichen

Hypogymnia psychodes

Whole lichen

Gold, brown

Indigo

Indigofera

Leaves

Blue

Not required

Ivy

Hedera helix

Berries

Yellow, green

Alum, tin

Madder

Rubia tinctora

Whole plant

Orange, red

Alum, tin

Maple

Acer spp

Bark

Tan

Copper sulphate

Marigold

Calendual spp

Whole plant, flower heads

Yellow

Alum

Nettles

Urtica dioica

Leaves

Beige, yellowy greens

Alum, copper

Onion

Allium cepa

Skins

Yellow, orange

Alum

Oak

Quercus spp

Inner bark

Gold, brown

Alum

Ochrolech-ina lichen

Ochrolech-ina parella

Whole lichen

Orange, red (when fermanted in urine then boiled)

Alum

Privet

Ligustrum vulgare

Leaves, berries

Yellow, green, red, purple

Alum, tin

Ragwort

Senecio

Flowers

Deep yellow

Safflower

Carthamus tinctoria

Petals

Yellow, red

Alum

Sloe-Blackthorn

Prunus spinosa

Sloe berries, bark

Red, pink, brown

Alum

Tea

Camelia sinensis

Leaves

Beige

Turmeric

Circuma longa

Root

Yellow

Wild mangosteen

Diospyros peregrina

Fruit

Grey, pink

Weld (wild mignonette)

Reseda luteula

Whole plant

Olive green

Alum, cream of tartar

Woad

Isatis tinctoria

Whole plant

Blue

Lime

Table 1. A list of plants commonly used for preparing dyes.

The choice of mordant for a particular plant is dependant upon the material with which it will be used. It is necessary to check a recipe before using a plant, or one can experiment to see what effect a mordant has for a particular application.

It is recommended that plants be grown specifically for the purpose of dyeing. Harvesting plants from the wild on a non-sustainable basis can endanger the survival of the plant. Many lichens are registered as protected organisms and it is illegal to gather them from the wild. One source of lichen is from timber mills where logged trees are being processed, but ask first!

Groundnuts03.gif
Figure 3: Groundnuts

Testing dyes

It is always useful and interesting to test the dye which is to be used on a sample of the yarn or fabric to be dyed. The outcome will depend on the fabric, the mordant that has been used and dye that has have been chosen. Testing is best carried out on a series of marked (for identification) samples, which have been mordanted with a number of different mordants. Tests can be carried out for light, water and washing fastness using simple standard test methods. Box 1 shows a simple test for washing fastness. Similar tests exists for water and light fastness (and are given in detail in the same book).

Box 1

Test method for fastness to washing

To test for fastness follow these steps:

1. Take two pieces of fabric about 5cm by 5cm, one of which is undyed cotton and the other undyed wool. Stitch them together along one side.

2. Take some sample strips of the dyed yarn and spread them evenly between the two pieces of cloth so that they overlap both sides. If dyed fibre is being tested a combed sample can be used in place of the yarn.

3. Sew around all four sides of the cloth so that the yarn is held in place.

4. Prepare a similar specimen with dyed materials that has satisfactory properties and place them in two jars with screw lids containing a solution of 5gm per litre soap or detergent solution at 30oC.

5. Agitate the two jars gently for 30mins, then remove the fabrics and wash them gently in clean water for 5mins. Open the stitching and separate the pieces to dry in air.


Examination:

6. Place the dyed yarn next to a sample of the same material which has not been tested, and compare the change which has taken place. Compare also with the control sample with satisfactory properties. If the dyeing being tested shows equal or less change than the satisfactory sample, then it is as good as the satisfactory sample.

7. Place the wool and cotton cloths next to samples of the same material which have not been tested and compare them with the cloths that have been tested with a satisfactory dyeing. Equal or less staining shows equal or better fastness.

Source: Dyeing and printing: a handbook, ITDG Publishing


Processing of the plant can take one of many forms, but usually takes the form of soaking or boiling the plant to extract the dye. Some plants, such as indigo, need special preparation for use. Some plants will need boiling to extract their dye while others can merely be soaked for extended periods. Detailed instructions for processing of a wide variety of plants can be found in some of the texts given in the reference chapter at the end of this document.

The process of dyeing

Application of the Dye

Dyeing can be carried out at any of the following stages in the textile manufacturing stage:

• The fibres can be dyed before they are spun. Fibre dyeing provides a deep penetration of the dye into the fibre, giving even colour and excellent colour-fastness.

• The yarn can be dyed after spinning but before the product is woven or otherwise fabricated. This is called package dyeing.

• Before the fabric is finished, it can be dyed in lengths (piece dyeing).This process allows manufacturers the opportunity to produce fabrics in their natural colours, and then dye them to order.

• In cross-dyeing, fabrics of two or more fibres can be dyed so that each fibre accepts a different dyestuff and becomes a different colour, through the use of appropriate dyestuffs for each fibre.


It is essential for the correct identification of the fibre or other fabric to be made before dyeing commences.

Methods of dyeing

There are a number of methods of applying dye to a fabric. Although the most common method used for applying natural dyes is the vat method, there are techniques which have been developed to allow patterns to be incorporated during the dying process. It is worth bearing in mind that using natural dyes is a complex art and the skills required for using natural dyes are learned over many years. Don’t be put off if you don’t get the desired results at the first attempt!

Vat Dyeing

In the simplest form of dyeing a textile material is immersed in dye and gradually brought to the boil. Alternatively the fibre is allowed to sit and soak for several hours or days. During this period, agitation is necessary to allow full penetration of the textile by the dyestuff. Depending on the type of fabric and dyestuff used, certain salts or acids may be added to assist absorption of the dye.

Groundnuts03.gif

The principal difficulty in dyeing mixed yarns and fabrics is to achieve the same colour in both fibres. Cotton fibres may, for instance, absorb dyes rapidly, while the wool fibres will have to be boiled over an extended period to reach the same depth of shade. This could lead to significant damage to the material. In this case a chemical compound would need to be used to restrain the rate at which the cotton fibre takes up the dyestuff.

The amount of dyestuff which is used is usually given in the recipe. It is usually quoted as a percentage weight of the fabric to be dyed. Box 2 demonstrates a typical, simple recipe for dyeing using natural dyestuff, in this case onion skins.

Box 2

Recipe for dyeing wool with onion skins

Fabric: applicable to wool or other animal (protein) fibres.

You will need:

• 100 grams of natural wool
• 30 grams of onion skins (use only the dry, brown, outer skins)
• 8 grams of alum (the mordant)
• 7 grams cream of tartar (the assistant)
• Some liquid detergent (the scouring agent)
• A water supply*


If a larger quantity of wool is to be dyed, increase the quantities proportionally.

Weigh the wool. All weights given are relative to the dry weight of the wool. Skeins of wool are tied loosely in several places to prevent tangling. In this case the recipe calls for 30% dyestuff i.e. the weight of the dyestuff is 30% that of the fabric to be dyed.

The wool should be scoured. This means getting the wool completely clean. For this the wool is soaked overnight in a liquid detergent solution. Rinse the wool well and gently squeeze out the excess water. Use lukewarm water and avoid sudden changes in the temperature of the water which cause the wool to felt or mat.

Next the skein will be mordanted. Dissolve the alum and cream of tartar in a little hot water and then add this solution to cool water in the mordant pan. Immerse the wetted yarn and then place the pan on the heat source. Slowly raise the temperature to 82oC (180oF) and simmer for 45 minutes. Leave to cool, then remove the wool and rinse well.

To prepare the dyebath, place the onion skins in the dyepan and cover them with water. Slowly heat the dyebath to boiling point. Simmer for about 45 minutes by which time all the colour should have been extracted from the onion skins. Remove from the heat, allow to cool and then strain of the liquid form the skins.

The dyeing process is then carried out. The mordanted, thoroughly wetted fabric is placed into the now cool dyebath. Replace the heat under the dyebath, bring the temperature up to boiling point and then immediately reduce the heat to 82oC (180oF) and simmer for 45 minutes or until the wool is the required colour. Remember that wool is darker when wet than when dry. Remove the wool from the dyebath if no further uptake of dye is required, or allow the fabric to cool with the liquid in the dyebath. Do not cool quickly with cold water.

When the skein of wool is cool, rinse it thoroughly in several changes of water until the water is clear, then wash the skein of wool in soapy water, rinse and allow to dry.

*Ordinary tap water is normally suitable for dyeing. If ‘soft’ water is called for then rain water can be used. A plentiful supply of fresh water is always required when dyeing.

Source: The Craft of Natural Dyeing, Jenny Dean


Batik

Batik is a starch resist-dyeing process, developed on the Island of Java in modern-day Indonesia. Colour is prevented from reaching certain areas of a fabric by covering these areas with molten wax. The fabric is starched prior to the design being drawn upon it. The wax is applied with a type of cup with a fine pouring spout, usually made of copper. The technique has been developed to a high art form in Indonesia from where it is exported to many parts of the world. Batik paintings, as well as sarongs and lengths of fabric, are produced. When the fabric is dyed, all waxed areas resist the dyestuff. The wax is then removed by placing the fabric in boiling water. For patterns with many colours the same procedure is repeated until the full design is completed.

Tie-dyeing

Tie-dyeing is another popular artisanal dyeing technique. In this resist-dyeing process, waxed thread is tightly tied around the areas chosen to resist the coloured dyestuff, and the fabric is dipped into the dye. The waxed thread is then removed and the fabric dried. This process can be repeated for each colour to be added.

File:P009a.gif
Wild Mangosteen

Obtaining unusual colours

Colours other than those obtained by simply using a single dye, can be obtained by mixing dyes or dyeing a fabric more than once in different dyebaths. The colour triangle on the next page is a useful tool in determining the colours needed to produce a required shade.

File:P009b.gif

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References and further reading

Foulds, John, Dyeing and printing: a handbook, ITDG Publishing, 1989. The text and line drawings describe chemical dyeing and printing techniques as they apply to small-scale operations. 128pp.

Sayadda R. Ghuznavi, Rangeen - Natural dyes of Bangladesh, Vegetable Dye Research and Development Society, Bangladesh, 1987. This interesting book gives listings of indigenous Bangladeshi plants as well as recipes for their use.

Dalby, Gill and Dean, Jenny, Natural Dyes in Luapula Province (Zambia): Evaluation of Potential for Production, Use and Export. Working Paper 22, Development Technology Unit, University of Warwick, Coventry CV4 7AL, UK. 1988.

Dean, Jenny: The Craft Of Natural Dyeing, Search Press, 1994 This guide tells how to grow and find, harvest, and use all NON-TOXIC dyes in nature. It is excellent for children. She lists dyestuffs that provide a full spectrum of colours and explains how to test plant dyestuffs for colour potential. 64 pgs, 30 colour photos, 16 illustrated charts, paperback.

Cowan, Wavell: Operating A Business In The Small Business Space. A must for anyone who contemplates starting a small business. Xeroxed, spiral bound, non-profit 67 pp.

McRae, Bobbie: Colors From Nature: Growing, Collecting, and Using Natural Dyes How to grow dye plants, recognise and collect wild plants, and even find dyes in the produce department of the grocery store. Step-by-step instructions for over a dozen naturally dyed crafts projects. 168 pp.

Useful addresses

Earth Guild, 33 Haywood Street Asheville NC 28801,
USA
Tel: +1 800 327 8448
Fax: +1 (704) 255 8593
E-mail: inform@earthguild.com or catalog@earthguild.com
Suppliers of natural dyes and dyeing equipment.

Vegetable Dye Research and Development Society,
P.O.Box 268,
Dhaka,
Bangladesh.
Carry out R&D and publish books on Natural Dyeing

The Crafts Council,
1 Oxenden Street,
London SW1Y 4AT.
United Kingdom
Tel: +44 (0)20 7930 4811

Khadi and Village Industries Commission,
Irla, Vile Parle,
Bombay 400056,
India

Society of Dyers and Colourists,
PO Box 244, Perkin House,
82 Graton Road,
Bradford BD1 2JB,
United Kingdom
Produce a Colour Index of all known natural and manufactured dyes, but it is very expensive.

Useful internet addresses

http://www.earthguild.com/products/Dyes/dye.htm Homepage of Earth Guild (see addresses section above).

http://www.slonet.org/~crowland/index.html Carol Todd’s Natural Dyeing Homepage. Sells books and electronic database of plants and natural dyes.

http://www.hillcreekfiberstudio.com/Workshops.html Hillcreek Fibre Studio. Runs workshops on weaving and natural dyeing. Based in the USA.

There are many recipes for natural dyeing given on the Internet. Enter a search on ‘Natural dyeing’ and this will yield a wealth of recipes, suggestions and ideas for the novice (and experienced) dyer.