Earthworms have been on the Earth for over 20 million years. In this time
they have faithfully done their part to keep the cycle of life continuously
moving. Their purpose is simple but very important. They are nature’s way of
recycling organic nutrients from dead tissues back to living organisms. Many
have recognized the value of these worms. Ancient civilizations, including
Greece and Egypt valued the role earthworms played in soil. The Egyptian
Pharaoh, Cleopatra said, “Earthworms are sacred.” She recognized the
important role the worms played in fertilizing the Nile Valley croplands after
annual floods. Charles Darwin was intrigued by the worms and studied them for
39 years. Referring to an earthworm, Darwin said, “It may be doubted whether
there are many other animals in the world which have played so important a part
in the history of the world.” The earthworm is a natural resource of fertility
and life.
Earthworms live in the soil and feed on decaying organic material. After
digestion, the undigested material moves through the alimentary canal of the
earthworm, a thin layer of oil is deposited on the castings. This layer erodes
over a period of 2 months. So although the plant nutrients are immediately
available, they are slowly released to last longer. The process in the
alimentary canal of the earthworm transforms organic waste to natural
fertilizer. The chemical changes that organic wastes undergo include
deodorizing and neutralizing. This means that the pH of the castings is 7 (neutral)
and the castings are odorless. The worm castings also contain bacteria, so the
process is continued in the soil, and microbiological activity is promoted.
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Vermicomposting is the process of turning organic debris into worm castings. The worm
castings are very important to the fertility of the soil. The castings contain
high amounts of nitrogen, potassium, phosphorus, calcium, and magnesium.
Castings contain: 5 times the available nitrogen, 7 times the available potash,
and 1 ½ times more calcium than found in good topsoil. Several researchers have
demonstrated that earthworm castings have excellent aeration, porosity,
structure, drainage, and moisture-holding capacity. The content of the earthworm
castings, along with the natural tillage by the worms burrowing action,
enhances the permeability of water in the soil. Worm castings can hold
close to nine times their weight in water. “Vermiconversion,” or using
earthworms to convert waste into soil additives, has been done on a relatively
small scale for some time. A recommended rate of vermicompost application is
15-20 percent.
Vermicomposting is done on small and large scales. In the 1996 Summer
Olympics in Sydney, Australia, the Australians used worms to take care of their
tons and tons of waste.They then found that waste produced by the worms was
could be very beneficial to their plants and soil. People in the U.S. have
commercial vermicomposting facilities, where they raise worms and sell the
castings that the worms produce. Then there are just people who own farms or
even small gardens, and they may put earthworms into their compost heap, and
then use that for fertilizer.
Vermicompost and its utilization
Vermicompost is nothing but the excreta of earthworms, which is rich in humus and nutrients. We can rear earthworms artificially in a brick tank or near the stem / trunk of trees (specially horticultural trees). By feeding these earthworms with biomass and watching properly the food (bio-mass) of earthworms, we can produce the required quantities of vermicompost.
Any types of biodegradable wastes-
- Crop residues
- Weed biomass
- Vegetable waste
- Leaf litter
- Hotel refuse
- Waste from
agro-industries
- Biodegradable portion of
urban and rural wastes
Phase of vermicomposting
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Phase 1
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Processing involving collection of wastes, shredding, mechanical
separation of the metal, glass and ceramics and storage of organic wastes.
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Phase 2
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Pre digestion of organic waste for twenty days by heaping the material
along with cattle dung slurry. This process partially digests the
material and fit for earthworm consumption. Cattle dung and biogas
slurry may be used after drying. Wet dung should not be used for
vermicompost production.
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Phase 3
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Preparation of earthworm bed. A concrete base is required to put the
waste for vermicompost preparation. Loose soil will allow the worms to
go into soil and also while watering, all the dissolvable nutrients go into
the soil along with water.
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Phase 4
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Collection of earthworm after vermicompost collection. Sieving the
composted material to separate fully composted material. The partially
composted material will be again put into vermicompost bed.
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Phase 5
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Storing the vermicompost in proper place to maintain moisture and allow
the beneficial microorganisms to grow.
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What Worms Need - The Five Essentials
Compost worms need five basic things:
- An hospitable living
environment, usually called “bedding”
- A food source
- Adequate moisture
(greater than 50% water content by weight)
- Adequate aeration
- Protection from
temperature extremes
These five essentials are discussed in more detail below.
Bedding
Bedding is any material that provides the worms with a relatively stable
habitat. This habitat must have the following characteristics:
High absorbency
Worms breathe through their skins and therefore must have a moist
environment in which to live. If a worm’s skin dries out, it dies. The bedding
must be able to absorb and retain water fairly well if the worms are to thrive.
Good bulking potential
If the material is too dense to begin with, or packs too tightly, then the
flow of air is reduced or eliminated. Worms require oxygen to live, just as we
do. Different materials affect the overall porosity of the bedding through a
variety of factors, including the range of particle size and shape, the
texture, and the strength and rigidity of its structure. The overall effect is
referred to in this document as the material’s bulking potential.
Low protein and/or nitrogen content (high Carbon: Nitrogen ratio)
Although the worms do consume their bedding as it breaks down, it is very
important that this be a slow process. High protein/nitrogen levels can result
in rapid degradation and its associated heating, creating inhospitable, often
fatal, conditions. Heating can occur safely in the food layers of the
vermiculture or vermicomposting system, but not in the bedding.
Requirements
- Housing: Sheltered culturing of worms is recommended to
protect the worms from excessive sunlight and rain. All the entrepreneurs
have set up their units in vacant cowsheds, poultry sheds, basements and
back yards.
- Containers: Cement tanks were constructed. These were
separated in half by a dividing wall. Another set of tanks were also
constructed for preliminary decomposition.
- Bedding
and feeding materials: During
the beginning of the enterprises, most women used cowdung in order to
breed sufficient numbers of earthworms. Once they have large populations,
they can start using all kinds of organic waste. Half of the entrepreneurs
have now reached populations of 12,000 to 15,000 adult earthworms.
i) Selection of suitable earthworm
For vermicompost production, the surface dwelling earthworm alone should be
used. The earthworm, which lives below the soil, is not suitable for
vermicompost production. The African earthworm (Eudrillus
engenial), Red worms (Eisenia foetida) and composting worm
(Peronyx excavatus) are promising worms used for vermicompost
production. All the three worms can be mixed together for vermicompost
production. The African worm (Eudrillus eugenial) is preferred over
other two types, because it produces higher production of vermicompost in short
period of time and more young ones in the composting period.
ii) Selection of site for vermicompost production
Vermicompost can be produced in any place with shade, high humidity and
cool. Abandoned cattle shed or poultry shed or unused buildings can be
used. If it is to be produced in open area, shady place is
selected. A thatched roof may be provided to protect the process from
direct sunlight and rain. The waste heaped for vermicompost production should
be covered with moist gunny bags.
iii) Containers for vermicompost production
A cement tub may be constructed to a height of 2½ feet and a breadth of 3
feet. The length may be fixed to any level depending upon the size of the
room. The bottom of the tub is made to slope like structure to drain the
excess water from vermicompost unit. A small sump is necessary to collect the
drain water.
In another option over the hand floor, hollow blocks / bricks may be
arranged in compartment to a height of one feet, breadth of 3 feet and length
to a desired level to have quick harvest. In this method, moisture assessment
will be very easy. No excess water will be drained. Vermicompost can also
be prepared in wooden boxes, plastic buckets or in any containers with a drain
hole at the bottom.
iv) Vermiculture bed
Vermiculture bed or worm bed (3 cm) can be prepared by placing after saw
dust or husk or coir waste or sugarcane trash in the bottom of tub / container.
A layer of fine sand (3 cm) should be spread over the culture bed followed by a
layer of garden soil (3 cm). All layers must be moistened with water.
Common Bedding Materials
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Bedding Material
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Absorbency
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Bulking Pot.
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C:N Ratio
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Horse Manure
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Medium-Good
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Good
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22 - 56
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Peat Moss
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Good
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Medium
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58
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Corn Silage
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Medium-Good
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Medium
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38 - 43
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Hay – general
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Poor
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Medium
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15 - 32
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Straw – general
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Poor
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Medium-Good
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48 - 150
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Straw – oat
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Poor
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Medium
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48 - 98
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Straw – wheat
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Poor
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Medium-Good
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100 - 150
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Paper from municipal waste stream
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Medium-Good
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Medium
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127 - 178
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Newspaper
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Good
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Medium
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170
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Bark – hardwoods
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Poor
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Good
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116 - 436
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Bark -- softwoods
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Poor
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Good
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131 - 1285
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Corrugated cardboard
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Good
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Medium
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563
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Lumber mill waste -- chipped
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Poor
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Good
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170
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Paper fibre sludge
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Medium-Good
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Medium
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250
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Paper mill sludge
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Good
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Medium
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54
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Sawdust
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Poor-Medium
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Poor-Medium
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142 - 750
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Shrub trimmings
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Poor
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Good
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53
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Hardwood chips, shavings
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Poor
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Good
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451 - 819
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Softwood chips, shavings
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Poor
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Good
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212 - 1313
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Leaves (dry, loose)
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Poor-Medium
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Poor-Medium
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40 - 80
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Corn stalks
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Poor
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Good
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60 - 73
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Corn cobs
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Poor-Medium
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Good
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56 - 123
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Paper mill sludge
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Good
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Medium
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54
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Sawdust
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Poor-Medium
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Poor-Medium
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142 - 750
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Shrub trimmings
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Poor
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Good
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53
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Hardwood chips, shavings
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Poor
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Good
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451 - 819
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Softwood chips, shavings
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Poor
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Good
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212 - 1313
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Leaves (dry, loose)
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Poor-Medium
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Poor-Medium
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40 - 80
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Corn stalks
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Poor
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Good
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60 - 73
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Corn cobs
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Poor-Medium
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Good
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56 - 123
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If available, shredded paper or cardboard makes an excellent bedding, particularly
when combined with typical on-farm organic resources such as straw and hay.
Organic producers, however, must be careful to ensure that such materials are
not restricted under their organic certification standards. Paper or cardboard
fibre collected in municipal waste programs cannot be approved for
certification purposes. There may be cases, however, where fibre resources from
specific generators could be sourced and approved. This must be considered on a
case-by-case basis. Another material in this category is paper-mill sludge,
which has the high absorbency and small particle size that so well complements
the high C:N ratios and good bulking properties of straw, bark, shipped brush
or wood shavings. Again, the sludge must be approved if the user has organic
certification.
In general, it should be noted by the reader that the selection of bedding
materials is a key to successful vermiculture or vermicomposting. Worms can be
enormously productive (and reproductive) if conditions are good; however, their
efficiency drops off rapidly when their basic needs are not met (see discussion
on moisture below). Good bedding mixtures are an essential element in meeting
those needs. They provide protection from extremes in temperature, the
necessary levels and consistency of moisture, and an adequate supply of oxygen.
Fortunately, given their critical importance to the process, good bedding
mixtures are generally not hard to come by on farms. The most difficult
criterion to meet adequately is usually absorption, as most straws and even hay
are not good at holding moisture. This can be easily addressed by mixing some
aged or composted cattle or sheep manure with the straw. The result is somewhat
similar in its bedding characteristics to aged horse manure.
Mixing beddings need not be an onerous process; it can be done by hand with
a pitchfork (small operations), with a tractor bucket (larger operations), or,
if one is available, with an agricultural feed mixer. Please note that the
latter would only be appropriate for large commercial vermicomposting
operations where high efficiency levels and consistent product quality is
required.
v) Worm Food
Compost worms are big eaters. Under ideal conditions, they are able to
consume in excess of their body weight each day, although the general
rule-of-thumb is ½ of their body weight per day. They will eat almost anything
organic (that is, of plant or animal origin), but they definitely prefer some
foods to others. Manures are the most commonly used worm feedstock, with dairy
and beef manures generally considered the best natural food for Eisenia, with
the possible exception of rabbit manure. The former, being more often available
in large quantities, is the feed most often used.
Common Worm Feed Stocks
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Food
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Advantages
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Disadvantages
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Cattle manure
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Good nutrition; natural food, therefore little adaptation required
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Weed seeds make pre-composting necessary
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Poultry manure
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High N content results in good nutrition and a high-value product
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High protein levels can be dangerous to worms, so must be used in small
quantities; major adaptation required for worms not used to this feedstock.
May be pre-composted but not necessary if used cautiously
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Sheep/Goat manure
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Good nutrition
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Require pre-composting (weed seeds); small particle size can lead to
packing, necessitating extra bulking material
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Hog manure
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Good nutrition; produces excellent vermicompost
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Usually in liquid form, therefore must be dewatered or used with large
quantities of highly absorbent bedding
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Rabbit manure
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N content second only to poultry manure, there-fore good nutrition;
contains very good mix of vitamins & minerals; ideal earth-worm feed
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Must be leached prior to use because of high urine content; can overheat
if quantities too large; availability usually not good
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Fresh food scraps (e.g., peels, other food prep waste, leftovers,
commercial food processing wastes)
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Excellent nutrition, good moisture content, possibility of revenues from
waste tipping fees
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Extremely variable (depending on source); high N can result in
overheating; meat & high-fat wastes can create anaerobic conditions and
odours, attract pests, so should NOT be included without pre-composting
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Pre-composted food wastes
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Good nutrition; partial decomposition makes digestion by worms easier and
faster; can include meat and other greasy wastes; less tendency to overheat.
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Nutrition less than with fresh food wastes.
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Biosolids (human waste)
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Excellent nutrition and excellent product; can be activated or
non-activated sludge, septic sludge; possibility of waste management revenues
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Heavy metal and/or chemical contam-ination (if from municipal sources);
odour during application to beds (worms control fairly quickly); possibility
of pathogen survival if process not complete
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Seaweed
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Good nutrition; results in excellent product, high in micronutrients and
beneficial microbes
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Salt must be rinsed off, as it is detrimental to worms; availability
varies by region
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Legume hays
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Higher N content makes these good feed as well as reasonable bedding.
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Moisture levels not as high as other feeds, requires more input and
monitoring
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Legume hays
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Higher N content makes these good feed as well as reasonable bedding.
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Moisture levels not as high as other feeds, requires more input and
monitoring
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Corrugated cardboard (including waxed)
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Excellent nutrition (due to high-protein glue used to hold layers
together); worms like this material; possible revenue source from WM fees
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Must be shredded (waxed variety) and/or soaked (non-waxed) prior to
feeding
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Fish, poultry offal; blood wastes; animal mortalities
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High N content provides good nutrition; opportunity to turn problematic
wastes into high-quality product
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Must be pre-composted until past thermophillic stage
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vi) Selection for vermicompost production
Cattle dung (except pig, poultry and goat), farm wastes, crop residues,
vegetable market waste, flower market waste, agro industrial waste, fruit
market waste and all other bio degradable waste are suitable for vermicompost
production. The cattle dung should be dried in open sunlight before used
for vermicompost production. All other waste should be predigested with
cow dung for twenty days before put into vermibed for composting.
vii) Putting the waste in the container
The predigested waste material should be mud with 30% cattle dung either by
weight or volume. The mixed waste is placed into the tub / container upto brim.
The moisture level should be maintained at 60%. Over this material, the
selected earthworm is placed uniformly. For one-meter length, one-meter breadth
and 0.5-meter height, 1 kg of worm (1000 Nos.) is required. There is no
necessity that earthworm should be put inside the waste. Earthworm will move
inside on its own.
viii) Watering the vermibed
Daily watering is not required for vermibed. But 60% moisture should be
maintained throughout the period. If necessity arises, water should be
sprinkled over the bed rather than pouring the water. Watering should be
stopped before the harvest of vermicompost.
ix) Harvesting vermicompost
In the tub method of composting, the castings formed on the top layer are
collected periodically. The collection may be carried out once in a week.
With hand the casting will be scooped out and put in a shady place as heap like
structure. The harvesting of casting should be limited up to earthworm
presence on top layer. This periodical harvesting is necessary for free
flow and retain the compost quality. Other wise the finished compost get
compacted when watering is done. In small bed type of vermicomposting method,
periodical harvesting is not required. Since the height of the waste
material heaped is around 1 foot, the produced vermicompost will be harvested
after the process is over.
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x) Harvesting earthworm
After the vermicompost production, the earthworm present in the tub / small
bed may be harvested by trapping method. In the vermibed, before
harvesting the compost, small, fresh cow dung ball is made and inserted inside
the bed in five or six places. After 24 hours, the cow dung ball is removed.
All the worms will be adhered into the ball. Putting the cow dung ball in
a bucket of water will separate this adhered worm. The collected worms
will be used for next batch of composting.
Worm harvesting is usually carried out in order to sell the worms, rather
than to start new worm beds. Expanding the operation (new beds) can be
accomplished by splitting the beds that is, removing a portion of the bed to
start a new one and replacing the material with new bedding and feed. When
worms are sold, however, they are usually separated, weighed, and then
transported in a relatively sterile medium, such as peat moss. To accomplish
this, the worms must first be separated from the bedding and vermicompost.
There are three basic categories of methods used by growers to harvest worms:
manual, migration, and mechanical. Each of these is described in more detail in
the sections that follow.
a) Manual Methods
Manual methods are the ones used by hobbyists and smaller-scale growers,
particularly those who sell worms to the home-vermicomposting or bait market.
In essence, manual harvesting involves hand-sorting, or picking the worms
directly from the compost by hand. This process can be facilitated by taking
advantage of the fact that worms avoid light. If material containing worms is
dumped in a pile on a flat surface with a light above, the worms will quickly
dive below the surface. The harvester can then remove a layer of compost,
stopping when worms become visible again. This process is repeated several
times until there is nothing left on the table except a huddled mass of worms under
a thin covering of compost. These worms can then be quickly scooped into a
container, weighed, and prepared for delivery.
There are several minor variations and/or enhancements on this method, such
as using a container instead of a flat surface, or making several piles at
once, so that the person harvesting can move from one to another, returning to
the first one in time to remove the next layer of compost. They are all
labour-intensive, however, and only make sense if the operation is small and
the value of the worms is high.
b) Self-Harvesting (Migration) Methods
These methods, like some of the methods used in vermicomposting, are based
on the worms tendency to migrate to new regions, either to find new food or to
avoid undesirable conditions, such as dryness or light. Unlike the manual
methods described above, however, they often make use of simple mechanisms,
such as screens or onion bags.
The screen method is very common and easy to use. A box is constructed with
a screen bottom. The mesh is usually ¼”, although 1/8” can be used as wel.
There are two different approaches. The downward-migration system is similar to
the manual system, in that the worms are forced downward by strong light. The
difference with the screen system is that the worms go down through the screen
into a prepared, pre-weighed container of moist peat moss. Once the worms have
all gone through, the compost in the box is removed and a new batch of
worm-rich compost is put in. The process is repeated until the box with the
peat moss has reached the desired weight. Like the manual method, this system
can be set up in a number of locations at once, so that the worm harvester can
move from one box to the next, with no time wasted waiting for the worms to
migrate.
The upward-migration system is similar, except that the box with the mesh
bottom is placed directly on the worm bed. It has been filled with a few
centimeters of damp peat moss and then sprinkled with a food attractive to
worms, such as chicken mash, coffee grounds, or fresh cattle manure. The box is
removed and weighed after visual inspection indicates that sufficient worms
have moved up into the material. This system is used extensively in Cuba, with
the difference that large onion bags are used instead of boxes. The advantage of
this system is that the worm beds are not disturbed. The main disadvantage is
that the harvested worms are in material that contains a fair amount of
unprocessed food, making the material messier and opening up the possibility of
heating inside the package if the worms are shipped. The latter problem can be
avoided by removing any obvious food and allowing a bit of time for the worms
to consume what is left before packaging.
xi) Nutritive value of vermicompost
The nutrients content in vermicompost vary depending on the waste materials
that is being used for compost preparation. If the waste materials are
heterogeneous one, there will be wide range of nutrients available in the
compost. If the waste materials are homogenous one, there will be only certain nutrients
are available. The common available nutrients in vermicompost is as follows
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Organic carbon
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:
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9.5 – 17.98%
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Nitrogen
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:
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0.5 – 1.50%
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Phosphorous
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:
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0.1 – 0.30%
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Potassium
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:
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0.15 – 0.56%
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Sodium
|
:
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0.06 – 0.30%
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Calcium & Magnesium
|
:
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22.67 to 47.60 meq/100g
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Copper
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:
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2 – 9.50 mg kg-1
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Iron
|
:
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2 – 9.30 mg kg-1
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Zinc
|
:
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5.70 – 11.50 mg kg-1
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Sulphur
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:
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128 – 548 mg kg-1
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xii) Storing and packing of vermicompost
The harvested vermicompost should be stored in dark, cool place. It should have minimum 40% moisture. Sunlight should not fall over the composted material. It will lead to loss of moisture and nutrient content. It is advocated that the harvested composted material is openly stored rather than packed in over sac. Packing can be done at the time of selling. If it is stored in open place, periodical sprinkling of water may be done to maintain moisture level and also to maintain beneficial microbial population. If the necessity comes to store the material, laminated over sac is used for packing. This will minimize the moisture evaporation loss. Vermicompost can be stored for one year without loss of its quality, if the moisture is maintained at 40% level.
The harvested vermicompost should be stored in dark, cool place. It should have minimum 40% moisture. Sunlight should not fall over the composted material. It will lead to loss of moisture and nutrient content. It is advocated that the harvested composted material is openly stored rather than packed in over sac. Packing can be done at the time of selling. If it is stored in open place, periodical sprinkling of water may be done to maintain moisture level and also to maintain beneficial microbial population. If the necessity comes to store the material, laminated over sac is used for packing. This will minimize the moisture evaporation loss. Vermicompost can be stored for one year without loss of its quality, if the moisture is maintained at 40% level.
- Vermicompost is rich in
all essential plant nutrients.
- Provides excellent effect
on overall plant growth, encourages the growth of new
- shoots / leaves and
improves the quality and shelf life of the produce.
- Vermicompost is free
flowing, easy to apply, handle and store and does not have bad
- odour.
- It improves soil
structure, texture, aeration, and waterholding capacity and prevents
- soil erosion.
- Vermicompost is rich in
beneficial micro flora such as a fixers, P- solubilizers,
- cellulose decomposing
micro-flora etc in addition to improve soil environment.
- Vermicompost contains
earthworm cocoons and increases the population and
- activity of earthworm in
the soil.
- It neutralizes the soil
protection.
- It prevents nutrient
losses and increases the use efficiency of chemical fertilizers.
- Vermicompost is free from
pathogens, toxic elements, weed seeds etc.
- Vermicompost minimizes
the incidence of pest and diseases.
- It enhances the
decomposition of organic matter in soil.
- It contains valuable
vitamins, enzymes and hormones like auxins, gibberellins etc.
Compost worms are not subject to diseases caused by micro-organisms, but
they are subject to predation by certain animals and insects (red mites are the
worst) and to a disease known as “sour crop” caused by environmental
conditions.
