Living organic soil from start through recycling

[Microbeman]

I'm a bit of an overdoer with the vermicompost. You can get perfectly fine product with a flow through or a regular plastic bin. In the case of the bin, just start them in about 3 inches of bedding/food and add at about one inch layers as you see them finishing the food you gave them. Once you reach the top, harvest them out and start over.

http://microbeorganics.com/keepingworms.pdf

The more dense the worms, the better and faster the product and the more they multiply. Only start new bins, once really super populated.

Leaving the worms in longer and making them redigest is optional and a luxury when you have too much vermicompost.

Earthworms are nature?s clean-up crew, aiding in the production of lush, humus-rich topsoil from spent plant and animal materials. These elegantly efficient organisms have been on earth for hundreds of thousands of years longer than humankind, largely untouched by evolution due to their nearly perfect adaptation to their role in nature.

Humankind has studied and learned to appreciate the talents of the earthworm, developing systems that capitalize on the natural role it plays in recycling organic matter back into humus. We now use earthworms for the remediation of organic ?waste? materials, reducing the pressure on landfills and aiding in the regeneration of our valuable topsoils.

When beginning a foray into the operation of worm driven organics systems it is important to be clear on the intended goal of the project. Worm systems are typically managed for one of three reasons; waste management, production of worm biomass, and production of castings. While worms are being grown, organic materials are being processed, and castings are being generated in all worm beds, management methods will vary to some degree depending on the focus of the system.

Vermicomposting is defined as the practice of using concentrations of earthworms to convert organic materials into usable vermicompost or worm castings. These systems focus on the waste material and managing it so that it can be successfully and efficiently processed in a worm system.

Castings production systems are worm-processing beds that use feedstocks specially blended so that castings have a specific nutrient value, chemical characteristic or cross section of microorganisms. The focus of these systems is on end product value.

Vermiculture systems focus on producing the maximum level of worm biomass possible in a given space.


The Amazing Earthworm
Researchers have identified and named more than 4400 distinct species of earthworm, each with unique physical, biological and behavioral characteristics that distinguish them one from the other. These species have been grouped into three categories, endogeic, anecic and epigeic, descriptive of the area of the natural soil environment in which they are found, and defined to some degree by environmental requirements and behaviors.

Anecic species, represented by the common nightcrawler (Lumbricus terrestris), build permanent vertical burrows that extend through the upper mineral soil layer, which can be as deep as 4-6 feet. These species coat their burrows with mucous that hardens to prevent collapse of the burrow, providing them a home to which they will always return and are able to reliably identify, even when surrounded by other worm burrows. When deprived of this burrow environment anecic worms will neither breed nor grow.

Anecic worms feed in decaying organic matter and are responsible for cycling huge volumes of organic surface debris into humus.

Endogeic species build extensive, largely horizontal burrow systems through all layers of the upper mineral soil. These worms rarely come to the surface, spending their lives deep in the soil where they feed on decayed organic matter and mineral soil particles. While most people believe all worms eat soil, it is only the epigeic species that actually feed on significant volumes of soil itself.

These worm species help to incorporate mineral matter into the topsoil layer as well as aerating and mixing the soil through their movement and feeding habits.

Epigeic earthworm species, represented by the common red worm (Eisenia fetida), are found in the natural environment in the upper topsoil layer where they feed in decaying organic matter. Epigeic worms build no permanent burrows, preferring the loose topsoil layer rich in organic matter to the deeper mineral soil environment. Even in nature these worms are found in highest concentrations in the forest duff layer or in naturally occurring drifts of leaves and organic debris rather than in soil. We can duplicate the preferred environment of these worm species in bin culture, and it is largely for this reason that it is epigeic worms only that are used in vermicomposting and vermiculture systems.

Oxygen requirements
Earthworms are oxygen-breathing animals that absorb oxygen directly through their skin. Oxygen is dissolved into mucous coating the worm?s skin and the dissolved oxygen passes through the skin and the walls of capillaries lacing the skin where it is picked up by hemoglobin in the worm blood and carried throughout the body.

Moisture requirements
Moisture is critical to the survival of all earthworm species because it is moisture within the worm?s body that gives it shape, enables it to move, and aids in the worm?s ability to absorb oxygen. To facilitate the absorption of oxygen the skin is very thin and permeable, meaning that the moisture within the body cavity is easily evaporated off, particularly in dry environments. The moisture range for most worm species is from 60-85%, which ensure the worm can absorb as much moisture as may be lost.

Temperature requirements
Specific temperature requirements and tolerances vary from species to species, though the ideal range for most epigeic worm species is between roughly 60-80? F. The worm?s ability to tolerate temperatures outside of ideal is highly dependant on the level of moisture in the system, with hot, dry conditions being the most lethal combination.

Nutritional requirements
Earthworms lack teeth and sufficient digestive enzymes of their own, relying instead on microorganisms to begin to rot and soften organic matter so it can be ingested, then relying on naturally occurring bacteria and fungi in their gut to digest their food. In the process of taking in this biologically active predigested organic matter the earthworm also ingests small particles of sand and soil, which lodge in their gizzard. As the organic matter and microbial life coating it move past this gizzard they are ground against the gritty particles lodged there and fragmented into smaller pieces, making them easier for the gut organisms to digest.

Researchers now understand that it is not from the organic matter itself, but from the bodies of the microbial life rotting the organic matter that epigeic earthworms derive the bulk of their most vital nutrients. Once thought to be detritus (debris) feeders, we now understand that the earthworm is actually a predator of microbial life, relying on microscopic bacteria, fungi, protozoa and algae as their major sources of nutrition. Thus, anything that will support microbial activity, that is, anything that rots, is potentially suitable food for earthworms. Materials that support the greatest level of earthworm activity are those that support the greatest and most diverse populations of microbial life.

PH requirements
As microorganisms break down organic matter it goes through a series of naturally occurring changes in pH. Because earthworms thrive in environments rich in decaying organic matter they are adapted to tolerate these pH fluctuations with little or no change in their activity levels. In nature worms are found in environments with a pH range from 4-9, with processing and reproductive rates being no different at an acidic 4 than they are at an alkaline 9. In fact, all things being otherwise equal, earthworms actually prefer an environment with a pH of 5 to 5.5, contrary to the popular belief that they prefer a neutral pH.

With a pH tolerance this wide it is highly unusual for pH to be a limiting factor in any worm system. Further, the radical and artificial adjustment of the pH through the addition of buffering agents like lime can actually have a detrimental effect on the system. The organisms present in a given environment of organic debris are there because they are suited to that environment and whatever fluctuation may naturally occur through the process of decay. When the nature of the system is suddenly and radically altered it forces many of these organisms into dormancy and sometimes kills them outright, thus reducing the availability of nutrition to the worms and potentially slowing the processing rate of the organic matter.

The addition of lime to any worm system is generally discouraged except in those extremely rare circumstances where the pH has dropped well below the worms? level of tolerance.

Ultra-Violet light response
All earthworms are photophobic to some degree, meaning they react negatively to bright light. The severity of the reaction depends on the species of worm, how bright the light and the level of light to which the worm is accustomed. For example, earthworms accustomed to some light exposure will react less negatively to sudden bright light than will worms accustomed to complete darkness. Some species of worm react negatively to bright light but are actually attracted by dim light.

Earthworms sense light through photoreceptive organs along their back and on the prostomium (sensitive lobe of tissue overhanging the mouth that the worm uses to probe and sense its environment).

Reproduction
Earthworms are hermaphrodites, meaning each worm possesses both male and female reproductive organs. Some earthworm species can be self fertile, meaning they can fertilize their own ova to produce young, and some species are parthenogenic, meaning fertilization of the ova by sperm is not necessary to produce young. Most earthworm species, however, require that two worms exchange sperm in order to produce young.

When worms mate they lay side by side with their heads pointed in opposite directions, making close contact along the upper segments of their bodies. They excrete a mucous that coats both worms and binds them together, preventing them from being easily pulled apart and ensuring environmental conditions like rain or dew do not interfere with the exchange of sperm.

The worms exchange sperm, storing the received seed in a pore on the skin surface just above the clitellum (the differently colored or thickened band that encircles the worm body). Once they exchange sperm, a process that may take hours, the worms move apart and eject their own ova into a pore on their skin surface near the sperm pore. They secrete a thick mucous around the clitellum, which hardens on the outside but remains sticky underneath, forming a band out of which the worm backs, drawing the band over its head. As the band passes over the pores holding sperm and ova they are picked up and held on the sticky underside. Once the worm has backed completely out of the hardened mucous band the ends close forming a cocoon with sperm and ova inside where fertilization takes place. Each worm will continue to produce cocoons until they have used all of the sperm received from their mate.

The length of time it takes for the baby worms inside the cocoon to mature and ?hatch? out, and the number of young in each cocoon depend on the worm species and environmental conditions.

Contrary to popular belief, worms are a closed species, meaning they can produce viable young only with sperm from members of their own species. They cannot be hybridized. In those rare circumstances when two worms from differing species have attempted to mate, the result was either no young being produced or, in rare circumstances, babies that were always sterile.

The worm cocoon is an incredibly tough structure, designed to protect the young inside from environmental extremes and even ingestion by other animals. Cocoons can be frozen, submerged in water for extended periods of time, dried and exposed to temperatures far in excess of what can be tolerated by adult worms without damage to the young worms inside. The cocoon can even be eaten by other animals, provided it can make it past the teeth, surviving the digestive process and passing out of the animals body in the manure! In areas of climatic extremes it?s likely that the adult members of epigeic worm species do not survive, but the cocoons do, repopulating the environment when environmental conditions return to a range that can support worm activity.

Earthworm cocoons are easy to spot in the worm bed. They are roughly the size of a large grape seed and similarly shaped, with one end rounded and the other drawn out to a point. When first dropped from the body of the parent the cocoon is a creamy, pearlescent yellow, darkening to a cola brown as the young worms within mature and prepare to emerge.

Earthworm species used in vermiculture
While earthworm taxonomists have identified thousands of individual worm species, only six have been identified as useful in vermicomposting systems to date. These species were evaluated based on their ability to tolerate a wide range of environmental conditions and fluctuations, handling and disruption to the worm bed, and for their growth and breeding rate. Earthworm species with a short generation time, meaning a relatively short life span and rapid growth and reproductive rate, have been identified as most effective due in large part to the high concentration of juvenile worms present in their populations. Juvenile worms, like human teenagers, are voracious consumers, keeping the processing rate of the system high and ensuring an ongoing succession of young worms.

The growth and reproductive rates of each worm species listed below are the maximum identified under ideal conditions. These rates decline the further environmental conditions within the system shift from ideal.

Please note the Latin name of each earthworm species. Common names can be very misleading and often vary between different regions of the world and even regions within a country. It is very difficult to be sure which species of worm is being discussed unless the Latin name is being used. Professional worm growers should know and use the Latin names of the worms they culture.

Eisenia fetida*/Eisenia andreii (common name, Red Worm)
There are two worm species listed here because in virtually all cultures of E. fetida, E. andreii is present. E. andreii so closely resembles E. fetida in behavior, environmental requirements, reproductive and growth rate, and appearance that the only way to distinguish between the two is through protein analysis. There are no apparent physical differences between the two species. For all intents and purposes these worms can be considered identical. Eisenia fetida is generally the only worm mentioned because the two are so closely associated and because fetida is typically the more populous of the two.

Eisenia fetida/Eisenia andreii are the worm species identified as the most useful in vermicomposting systems and the easiest to grow in high-density culture because they tolerate the widest range of environmental conditions and fluctuations, and handling and disruption to their environment of all species identified for this purpose. E. fetida/E. andreii are also common to almost every landmass on earth, meaning there is essentially no concern over importing potentially alien species to an environment where they might cause damage.

While this worm species is considered the premier worm for most applications, it is a small worm, not always suited for use as bait.

? Temperature range: Minimum; 38? F, maximum; 88? F, ideal range; 70? F 80? F.

? Reproductive rate: Approximately 10 young per worm per week under ideal conditions.

? Average number of young per cocoon: Approximately 3.

? Time to emergence from the cocoon: Approximately 30-75 days under ideal conditions.

? Time to sexual maturity: Approximately 85-150 days under ideal
conditions.
*Note: The spelling ?fetida? was changed a few years ago to ?foetida? then subsequently changed back for reasons clear only to a few earthworm taxonomists. The different spellings do not denote different species. Information on this species can be found under both spellings, though the correct spelling is ?fetida?.

Eudrilus eugeniae (common name, African nightcrawler)
This worm is a semi-tropical species, meaning it cannot easily tolerate cool temperatures and is usually grown indoors or under temperature controlled conditions in most areas of North America. E. eugeniae is a large species, well suited for use as a bait worm, but does not tolerate handling or disruption to its environment.

This species is used in some vermicomposting systems around the Mediterranean region and in some areas of eastern Asia.

? Temperature range: Minimum; 45? F, maximum; 90? F, ideal range; 70? F 80? F.

? Reproductive rate: Approximately 7 young per worm per week under ideal conditions.

? Average number of young per cocoon: Approximately 2.

? Time to emergence from the cocoon: Approximately 15-30 days under ideal conditions.

? Time to sexual maturity: Approximately 30-95 days under ideal conditions.

Amynthas gracilus (common name, Alabama or Georgia jumper)
A. gracilus is another large worm species well suited for use as bait. It is also a tropical species with a poor tolerance for cold temperatures. This worm tolerates handling and disruption to the worm bed as well as does E. fetida and is generally considered an easy worm to culture provided appropriate temperatures can be maintained.

A. gracilus is used in a few vermicomposting systems in Malaysia and the Philippines.

? Temperature range: Minimum; 45? F, maximum; 90? F, ideal range; 70? F 80? F.

? Reproductive rate: Undetermined, though believed to be similar to E. eugeniae.

? Average number of young per cocoon: Undetermined, though believed to be similar to E. eugeniae.

? Time to emergence from the cocoon: Undetermined, though believed to be similar to E. eugeniae

? Time to sexual maturity: Undetermined, though believed to be similar to [I E. eugeniae[/I]

Perionyx excavatus (common name, Indian Blue worm)
Perionyx excavatus is a beautiful worm with an iridescent blue or violet sheen to its skin clearly visible under bright light. It is a very small worm, poorly suited as fishing bait, but has an impressive growth and reproductive rate far in excess of the other species grown in bin culture.

This is another tropical worm species with a very poor tolerance for low temperatures, fluctuations in the bin environment, handling or disruption to the system. P. excavatus is often referred to as ?the Traveler? for its tendency to leave the bin en masse for no "apparent" reason.

Due to it?s temperamental nature this species is rarely used in vermicomposting systems in North America, though it is naturally occurring at low population levels in systems in contact with the soil in the southeastern US and most tropical regions of the world.

? Temperature range: Minimum; 45? F, maximum; 90? F, ideal range; 70? F 80? F.

? Reproductive rate: Approximately 19 young per worm per week under ideal conditions.

? Average number of young per cocoon: Approximately 1.

? Time to emergence from the cocoon: Approximately 15-21 days under ideal
conditions.

? Time to sexual maturity: Approximately 30-55 days under ideal conditions.

Eisenia hortensis (European nightcrawler)
E. hortensis is a large worm species well suited for use as a bait worm. Its ideal temperature range is a bit cooler than is that of E. fetida and it requires higher moisture levels than do the other species tested for use in bin culture and vermicomposting, but the species tolerates handling and disruption to its environment, and environmental fluctuations very well.

Because this worm has a very low reproductive and growth rate, relatively speaking, it is considered the least desirable species of those tested for either bin culture or vermicomposting systems. It is used in a few vermiprocessing systems in Europe for the remediation of very wet organic materials.

? Temperature range: Minimum; 45? F, maximum; 85? F, ideal range; 55? F 65? F.

? Reproductive rate: Just under 2 young per worm per week under ideal conditions.

? Average number of young per cocoon: Approximately 1.

? Time to emergence from the cocoon: Approximately 40-125 days under ideal conditions.

? Time to sexual maturity: Approximately 55-85 days under ideal conditions.


All rights reserved, Kelly Slocum, 2001

 

[Microbeman]

More Kelly;

Lacking teeth, earthworms rely on microorganisms to begin breakdown of organic materials so they can be ingested. Organic materials resistant to decay, like orange rinds, can take a significant amount of time to be sufficiently decomposed for the worm to take in. As such, oranges can sometimes remain undisturbed in the bin long enough to become a host for mold and fungi. These molds are breaking down the rinds, however, helping to gradually make them available to the worms. They are not a danger to you, your worms, your pets, or your plants when you later use the finished material in the garden. There is some suggestion on the net that the presence of d-limonene in citrus oils is inhibitory to earthworm activity, but this concern is typically so overstated as to be incorrect. It is highly unlikely that there is sufficient d-limonene in the rinds of one or two citrus fruits tossed into the bin to have a measurable impact on the worms. Further, citrus oil is rather quickly volatilized and broken down by biological activity. Once the rind is sufficiently decayed to be available to the worm most of the d-limonene is gone.

Another myth often perpetuated about worms and citrus is concern over low pH. Worms are tolerant of a pH range from 4-9, often exhibiting little difference in activity throughout this range. Pineapple, grape pumice and citrus, all acidic materials, are all successfully processed in vermicomposting systems without the necessity of pH adjustments. If the possibility of pH being an issue was troubling you know that it is highly unlikely that the worms are avoiding the citrus due to acidity. Typically citrus rinds remaining in a bin for extended periods are not being rejected by the worms, they simply take longer to be sufficiently broken down so the worm can ingest them than most materials used as worm bin feedstock. Molds growing on the rind are aiding the process. It is not necessary that you remove the moldy oranges. Go ahead and add that nice leaf cover and in a couple of weeks those moldy oranges will be gone completely.

Kelly

If you’ve ever looked into an active worm bin you might have noticed that the worms were not the most numerous organisms visible. Beneficial mites, springtails, small white worms and a host of other multi-legged and even no-legged critters were likely visible without the aid of a magnifying lens. Place a sample of the organic material from the bin under a microscope and it becomes clear that the populations of microscopic organisms teeming in the material vastly outnumber the host of organisms visible to the unaided eye. It sometimes begs the question; why do we call this just a worm bin?

In vermicomposting we tend to focus our attention and bin management on the needs of the earthworm because we recognize that worms in the system decrease decomposition time and produce valuable castings. It’s important to remember, however, that a healthy, productive bin is an ecosystem possessed of an incredible diversity of life. The activity of the whole of the system’s living organisms is greater than the sum of its parts and each of these organisms is filling a vital niche in stabilizing the organic material.

Earthworms alone cannot complete the task of converting organic wastes. Lacking teeth and sufficient digestive enzymes of their own, they rely on microorganisms to begin breaking down the organic matter, fragmenting and softening the material so it can be ingested. In the process of taking in the decaying organic material the earthworm also ingests those microorganisms, deriving the majority of its vital nutrients from their bodies rather than from the organic matter itself.

The microscopic bacteria and fungi are aided in their work of decaying the organic material by many of the insects and arthropods we see crawling in the bedding. These organisms shred and break up the organic materials, exposing more of the surface area to microbial attack. In their digestive systems acids, enzymes and gut organisms digest the material and what is not absorbed into the animal’s body is passed as feces. This fecal matter becomes a predigested, simplified food for other organisms, like worms, to further reduce.

Mold and fungi are highly beneficial decomposers common to all worm bins as well as themselves being a food source for earthworms. Damp, dark environments rich in organic matter are natural environments for the growth of these organisms, which secrete enzymes that aid in breaking down some of the most resistant materials in the bin.

Following is a list of some of the most common of the beneficial organisms living in a healthy worm bin:

Ants (Formicidae)
These highly successful insects generally do not live in healthy worm systems but may occasionally visit in search of food. Ants tend to prefer conditions dryer than are found in active worm bins and rarely nest in environments with so many competing invertebrate species. Their continual presence in the system may indicate a need to increase moisture, which will usually discourage or drive them out. While it’s not required that ants be prevented from visiting an outdoor worm bin, keeping the bin elevated with each leg in a can of soapy water will create a barrier, preventing them from entering the system.

Centipedes (Chilopoda)
These multi-legged predators in the worm bin thrive in the damp environment where they feed on other invertebrate residents. They have a pair of huge, formidable pincers that curve from behind the head with which they can subdue prey larger than themselves. They are typically dark brown to reddish/tan in color, with a flattened, cylindrical body and one pair of legs per body segment.

While centipedes do feed on earthworms, it is unusual to have more than one or two in a worm bin, which is an insufficient number to significantly impact the worm population. Still, it is recommended that they be removed from the bin as they can inflict a non-poisonous but painful bite if we accidentally come into contact with one while feeding the system.

Fruit flies (Diptera)
While generally considered a nuisance, fruit fly larvae are voracious decomposers of fruit and vegetables wastes and, as such, are beneficial residents of the worm bin. If the system is being operated outdoors where the nuisance factor is negligible there is no need to attempt to control their numbers. If the system is being operated indoors, pre-treating the feedstock can prevent them. Most fruit flies enter the system as eggs and larvae on the peels of the fruits and vegetables we feed to the bin. Freezing or microwaving the food scraps before adding them to the system will kill the eggs and larvae, preventing the flies from becoming established. Ensuring the food scraps are never left exposed on the surface of the material will prevent mature fruit flies in the environment from being attracted to the bin and using it as a breeding ground.

Preventing a fruit fly invasion is simpler than controlling one. Should the flies become established in your bin and require control, inoculating the system with beneficial nematodes in conjunction with pre-treatment of the feed stock will eliminate them in roughly 10 to 14 days.

Fungus gnats (Diptera)
These small fly species are often mistaken for fruit flies but lack their brightly colored, bulbous eyes. The small, black fungus gnat more closely resembles a mosquito without the long proboscis.

The adult fungus gnat is harmless, feeding on fungal growth in the worm bin. Their larvae will feed on decaying organic matter in the bin, but will also feed on tender plant root hairs if the eggs are deposited onto soil surfaces. In outdoor environments this is not a problem as competition controls their numbers, but in indoor areas the fungus gnat larvae can damage houseplants.

Fungus gnats are not typically introduced to the home from the worm bin, rather, they may find the bin when they are already present in the home. The bin environment, however, is ideal for the adults and can support their populations inside homes. Fungus gnats can be readily controlled by inoculating the bin and all houseplant soils with beneficial nematodes, which feed on the fly larvae, typically eliminating them within about 10 days.

Millipedes (Diploda)
The slow-moving millipede resembles the centipede, but has a more rounded body shape, darker coloring and two pairs of legs per body segment. They are beneficial decomposers in the system, found through all layers of material, are harmless to humans, pets and plants, and do not require control.

Mites (Acarina)
These tiny cousins of spiders can be among the most numerous of the visible decomposers in a healthy worm bin. There are more than a dozen species of mites potentially present in a healthy system, all with four pairs of legs, large bodies and tiny heads, and in colors ranging from white to shades of reddish brown. Some mites are predators of other insects in the system, some feed on fungi and molds, and some on the organic matter itself. Despite web sites with statements to the contrary, mites species predatory on earthworms are not common and are essentially unheard of in worm bins.

It is possible, though uncommon, for mite populations in the bin to bloom on the surface of the material so densely that they cover it entirely . Such mite blooms are typically associated with low oxygen penetration in the worm bed, often brought about by too much moisture and/or too little ability for air to move into the system. The mites, in response to the need for more air, congregate on the surface of the organic matter instead of spreading their population throughout the bin, as they normally do. Correcting the airflow problem will encourage the mites to spread through the bin once again.

Molds and fungi
Mold and fungi are present in any cool, damp environment rich in organic matter. Using their tiny, threadlike hyphae they penetrate into the organic debris and secrete enzymes that reduce the material so they can absorb the nutrients. Their presence in the bin does not require control, but those suffering from severe mold allergies should keep the bin outdoors or in well-ventilated locations to prevent irritation.

Pot worms (Enchytraeidae)
These tiny, threadlike, segmented white worms are among the most commonly cultured worms in the world as they are a prized tropical fish food. Common to healthy worm bins, they feed on decaying organic matter in the system. It is not necessary to attempt to control their numbers.

Slugs (Stylommatophora)
These unpopular invertebrates will appreciate the cool damp conditions of the worm bin to ride out the heat of the day. Some species of slug are omnivores and will aid the beneficial organisms in the system in breaking down the organic matter. While there are carnivorous slug species that feed on earthworms, they eat so few of them as to be a negligible problem.

Slug control is not required but if desired, is best affected by hand picking them from the system.

Black Soldier Fly larvae (Diptera)
The larvae of the black soldier fly can be an intimidating and ugly resident of the worm bin, but is a voracious, beneficial decomposer of organic matter and is neither dangerous to the worms nor a health hazard to the humans managing the system, our pets or our plants.

One half to one inch long, segmented, and dirty white/gray, darkening from orange to black at the front end, these larvae can bloom in massive numbers in an outdoor worm bin. The are not found in indoor systems as adult soldier flies will not willingly enter buildings. Control is not necessary, nor is it advantageous as the larvae quickly fragment the organic material in the system and their fecal matter becomes an excellent nutrition source to the worms. Worm systems harboring black soldier fly larvae are among the most efficient systems in operation.

Sow and Pill bugs (Isopoda)
Known as woodlice, slaters and roly-poly bugs, these crustaceans are welcome residents of healthy worm bin where they feed on the tough woody material that is resistant to microbial attack. It is not necessary to control their populations in the bin.

Sow and pill bugs so closely resemble each other in appearance and behavior that, while different species, they can be viewed as the same organism in the worm bin. They are light brown to dark gray with an armored, segmented shell, seven pairs of legs and antennae.

Springtails (Colembola)
Springtails are often the most numerous of the visible decomposers in the worm bin. While some are dark brown with a spring mechanism, called a fercula, that enables them to jump impressive distances, the most numerous of the colembolans found in the worm bin are tiny white insects that lack the ability to spring. These white springtails will frequently cover the bedding material so thickly that it appears to be frosted.

Springtails are often small enough to walk across the head of a pin and range in color from brown to white. As insects, they possess six legs and a pair of stubby antenna. They are highly beneficial in any environment of decomposing organic matter and controlling their numbers in the worm bin is neither beneficial nor necessary.


Live and let live
Fears sometimes arise over the presence of many of the invertebrate residents of the bin as well as over the molds and fungi that may be present. As a culture we have been conditioned to see these organisms as harmful and in need of control or eradication. Concerns over the possibility that the insects may damage houseplants or infect pets, or that molds will spread disease are not uncommon. It’s important to remember, however, that the vast majority of the organisms living in the bin are there because they feed on dead and decaying organic material, or because they feed on the other organisms feeding on the decaying organic material. They have no interest at all in living plant or animal tissue or they would be found in environments where these preferences could be met. They do not spread disease, rather, the majority of the organisms in the worm bin are competitors of disease causing organisms and actually reduce health risks! The worm bin residents are beneficial to the processing of organic matter and should be left alone to work their magic side by side with the worms. Operating a worm bin means supporting an ecosystem, and a healthy ecosystem needs a diverse population of organisms in order to thrive.

All rights reserved, Kelly Slocum, 2001

Worms derive their nutrients from the bodies of microorganims that decay organic materials (OM). Once the OM has begun to rot it softens or fragments into small pieces that the worm can take in to its small mouth. Once in the gut the worm digestive process selects the microorganisms living on and decaying the OM as its nutrition source. The OM itself is moved on down the intestine where it is reduced by a different group of bacteria and fungi that live in the worm gut, then wrapped in a mucous coat and passed from the body as a cast.

Vermicomposting systems are specifically designed to receive regular inputs of raw OM, (we typically refer to this as feedstock) which keeps the microbiology in the system at very high levels. Bedding materials in the bin are tyically high in carbon; things like shredded leaves, paper, cardboard and straw, and this carbon is balanced by the relatively high nitrogen in the food scraps or manure we add to the bin as feedstock. When the carbon and nitrogen are balanced there is an ideal source of nutrients for the bacteria and fungi pivotal to the worm diet, and their populations bloom in response. When microbes bloom, worm activity is optimized.

Let's debunk this myth that worm castings are bad for worms. Worms need the most biologically active environment they can find in order to grow at maximum. The cast of the worm can be as much as six times MORE biologically active than is the OM they ingest. As such, castings are beneficial in the system since they increase the microbial activity. In fact, worms will reingest their own castings over and over again, even in the presence of a rich food source. Some of the most productive worm beds in the world are maintained by removing castings just once per year. Now, having said that, castings can also be very dense. If you get a castings build up low in the bin it can sometimes restict air movement. You'll want to watch bin conditions and, if you find the worms are reacting to low O2 levels, clean out the castings.

Be very aware that the internet is loaded with overly complex and outright WRONG information about how to grow worms. This is not a complex issue and worms in nature do it without all the gyrations some humans seem to feel is necessary to aid them.

Are you being impatient? I would be shocked if you were exhibiting the patience necessary for vermicomposting! :: None of us, when we first began our foray into worms, was patient, and some of us have never gotten over our impatience! You're being normal, which likely means you are expecting a bit too much a bit too soon. Do relax a bit about the little buggers and enjoy the process. And remember, Worms thrive on five things:

Air
Water
Decaying organic matter (OM)
Time
Neglect

Kelly S

 

[Heliopolis]

That's an excellent little compendium of vermicompost, Microbeman. Thanks for sharing!

 

[MrSterling]

Yeah I stopped putting dolomite in a while ago and see no difference. A penny saved is a penny earned.

 

[schwagg]

Schwagg:

How does the agave compare ubder the scope to molasses?

MM i like it so far. for the price i'll go back to BSM once it's finished. i need to run more teas with just the agave and not the catalyst to get a better idea of how well it can work. throwing two new things into a tea at once doesn't give me a fair assesment of each particular item.

nice read there MM! love the worm knowledge!

 

[ClackamasCootz]

From the Pacific Northwest.......

Ain't this rain storm a f*ckin' hoot?

 

[Microbeman]

From the Pacific Northwest.......

Ain't this rain storm a f*ckin' hoot?

Sucks! I think my drain field just flooded.

 

[ClackamasCootz]

what would be a good "starter" amount?

unclefishstick

Whatever your financial situation allows - LOL

One way to cut costs would be to start with a combination of worm and cocoons. You should be able to buy 1,000 cocoons online for about $20.00 with discounts for multiple units. I paid something like $50.00 for 3,000 Red Wiggler cocoons a couple of years ago.

Use MM's information on hatch rates, etc. and kinda go from there.

Blue Ridge Vermiculture was the one I went with but shop around if you're interested.

CC

 

[ClackamasCootz]

Sucks! I think my drain field just flooded.

The Oregon Coast was hit with > 100 mph winds besides taking the brunt of the rain before it moved inland to Portland. Seattle took some big hits as well.

Rain is forecast for the next 7 days......

 

[schwagg]

i ordered eggs from blue ridge, still have the same worms up and running. no complaints here.

 

[rrog]

Curious, has anyone read or heard reviews on the book True Living Organics by Rev? Just wondering if there's a folklore component or if it's a solid read.

 

[Coba]

The Rev: Quality and control. I hate synthetic grown weed – I mean smoking it – and I also hate that corporations, who make synthetic delivered nutrients make it seem like the way you grow plants is their way, and they have everyone brainwashed and these peeps couldn’t grow worth a damn in the natural world. Helpless, without the pretty pretty bottles of synthetic snake oil, heh heh; I have done some research into this amigo, and it is my belief that smoking synthetic grown weed sucks for more reasons than the hot/harshness of the smoke compared to TLO. Reading a bunch of innocuous looking acronyms like ‘EDTA’ isn’t impressive, and that’s how it’s supposed to come across. Look into those acronyms sometime if you want some stunning learning and dark amusement.

All natural (like TLO) herbs are pure planet Earth baybee, and I know exactly what I am smoking, and it is elegant. This is my Kung Fu, and it is strong.

I like his attitude...

 

[unclefishstick]

The Oregon Coast was hit with > 100 mph winds besides taking the brunt of the rain before it moved inland to Portland. Seattle took some big hits as well.

Rain is forecast for the next 7 days......

i remember those kind of storms from when i lived in port orford many a moon ago...

 

[rrog]

I downloaded his book this AM and read through it. Seems like an awful lot of CalMag and Botanicare, etc. Like a holdover from hydro days or something. Overall a good book.

I think anyone going organic should read Teaming With Microbes. Having a clear understanding of soil properties and microbial interaction is important, I think.

 

[Coba]

I never knew TLO was a coined catch phrase until I just now read it. :faceinpalms:

what's kind of ironic is the first time I read the acronym TLO was in the organic section at Garden Web.

 

[BlueJayWay]

Was it waaaaay back in this thread (or another?) where Rev's high times article, or wherever, was discussed, ya know his "spikes" and all that.

I had high hopes for Soma's book, which i had wanted to get a hold of a dozen years ago when i started down this path, well i found it as an E-book the other day and I think the only thing I took away from it was his indoor bed design, oh and made me want to meditate other than that 'twas baby steps compared to whats growin' on in here

 

[Coba]

oh that's right, the spikes and layers... and how nothing really grows in a spot that a real "spike" would be found in nature like a dead skunk or a whole lot of mammal urine, etc...


gascan,
Is $2.50 a pound a good price on a 50lb bag of Thorvin Kelp delivered to my front door?

 

[BlueJayWay]

^^^^ thanks for verifying I wasn't goin' crazy LOL

 

[BlueJayWay]

From the Pacific Northwest.......

Ain't this rain storm a f*ckin' hoot?

Statistically, Nov 19th is the rainiest day of the year for many locations in the PNW, specifically seatac, of which this year was the wettest (of the wettest) for that particular location.

Weather - the other hobby that takes up the rest of my time

you PNW'ers may get an artic outbreak i.e. cold snap, towards the very end of the month - would be expected headed into this time of year, eventually anyways....

 

[ClackamasCootz]

Spike's - great name for a Levi/Leather bar in West Hollywood......