1. RESOURCE RECOVERY TECHNOLOGY: COMPOSTING & VERMICOMPOSTING

2. Composting
Composting is the controlled decomposition of organic materials by micro-organisms in presence (aerobic) or absence (anaerobic) of oxygen.
Heat
CO2
NH3
Water vapor
Organic materials
Nitrification
Oxygen O2

3. Aerobic composting
During aerobic composting process, microbes that thrive in the presence of O2 break down the organic mineral forms and give rise to stable humus composed humic substances.
Moisture content of % is optimum for carrying out aerobic composting.
Microbes initiate the process of composting in presence of energy source (carbon), nutrients, moisture and oxygen content.

4. Cont-
Microbial respiration can contribute to the CO2 flux in to the atmosphere.
Respiration also produces heat that can derive moisture from the compost pile.
Ideal temperature for active compost piles range from C.
At such high temperature, pathogens and weed seeds are destroyed.

5. Cont-
During aerobic composting, loss of mass is largely governed by gaseous loss of CO2 and water vapor.
Towards the end of the composting process, mass and volume of the initial substrate may be reduced by 50%.

6. Nitrogen content in compost
Initially, total N-contents of the raw material (waste) are present in organic form.
This organic N gets converted to NH4-N during the decomposition process.
NH4-N thus produced can either get volatilize or get converted to NO3-N.
As NO3-N is soluble in water, therefore, if compost leaching occurs, N loss may amount from ≥ 50%.
Hence, lesser the leaching, richer the compost.

7. Phosphorus content in compost
Loss of phosphorus is negligible in a composting system.
Total P content in compost pile is present in organic form.
There is no volatile pathway for P loss.

8. Potassium content in compost
Potassium (K) is, another macro-nutrient for plant growth, present in inorganic, soluble form.
It is devoid of any loss from volatilization.
As there is no volatile loss of K, it tends to accumulate in the end-product of composting material.
Due to its affinity to accumulate and solubilize, K-loss may occur from leaching of the compost.

9. Cont-
N and P contents in finished compost are present in slowly biodegradable organic forms.
Therefore, when compost is applied to the soil, N and P gradually become bio-available.
However, as K content is already present in soluble form, so, it can directly be absorbed by the plants from compost amended soil.

10. Cont- Composted waste can be stored for long periods,
It attracts less flies, has fewer pathogens, and weed seeds.
Compost is an excellent soil conditioner.
Composting reduces the mass and volume of raw materials and transforms it in to a valuable product.

11. Structure of a compost bin
Compost bin : Perforated
Width : m
Length: m
Height: 0.3 m
Time : 3-5 months

12. Anaerobic composting
It is the slow decay of organic matter through fermentation
Unlike aerobic composting, pile will not heat up (maximum temperature C)
Micro-organism (Clostridium sp., Bacteroides sp., Bacillus sp., Pseudomonas sp.) that thrive in a low-oxygen environment reduce N, P, S, or O containing compounds found in organic matter to yield humus, gases, organic acids, and nutrients.

13. Structure of an Anaerobic bin
Anaerobic composting pits or bins should be made or located in a spot with good drainage, but not near to waterways or drainage courses.
Moisture : 60-70%
Time : 5-6 months- pits, 3-4 months-bins

14. Setting up anaerobic system
Capacity: Approx. 35 gallons or more.
Two bins should be used to allow for continuous composting.
Lining of the bin-bottom should be ¼’’ bird wire in order to prevent scavengers, but to allow earthworms to enter.

15. Materials to an-aerobically compost
Non-fatty kitchen scraps
Houseplant clippings
Grass clippings (small amounts)
Egg shells
Coffee grounds and filters
Tea bags
Pet and human hair
Wood ash (small amounts)
Untreated paper towel and tissue

16. Materials not to anaerobically compost….
Pet or human waste (Contains pathogens and parasites)
Meat and bones
Animal fat or oil
Dairy products
Barbeque briquettes or ashes
Woody yard trimmings
Large quantities of leaves

17. How anaerobic system works
Anaerobic composting works best with nitrogen-rich materials such as non-fatty kitchen scraps and soft grass clippings.
Avoid adding carbon-rich materials such as dry leaves, saw dust and woody yard waste.
Don’t open your anaerobic composting bin more than two times per week.
More the surface area for the micro-organisms to work on, the faster the materials will decompose.

18. Conti- Always maintain the moisture of the anaerobic compost bins.
Optimum moisture is 60-70%.
Time required for reaching maturity is up to 3 months.
40-500C is optimum temperature to destroy pathogens dangerous to people and pets
The sign of a healthy bin is pile with a ‘slimy’ consistency and slight sulfur odor.
Presence of insect larvae, worms, beetles etc. indicate a productive bin.

19. Vermicomposting
Vermicomposting is a type of composting carried out using some species of earthworms to accelerate the process.
Microbial activity of earthworm gut promotes fragmentation of the consuming substrate.
During this process, important plant nutrients in the organic materials (N, P, K, and Ca) are released and converted through microbial action in to soluble forms and become bio-available.

20. Parameters
Aerobic composting
Vermicomposting
Prior
During
After pH
6-8
6-8.5
Time (months)
2-3 -
2-3 (summer)
3-5 (winter)
Optimum temperature (0C)
50-60
18-25,
35 (max)
Height of pile (m) 4
0.6
C/N ratio
30-35/1
30/1
20/1
Humidity
40-65
Table: Comparison of different parameters between two methods of composting

21. Table : Comparison of various aspects of vermicomposting species of earthworms
Eisenia fetida
Eudrillus euginae
Perionyx excavatus
Eisenia andrei
Duration of life cycle (days)
±70
±60
±46
Growth rate (mg per worm per day) 7 12
3.5
Maximum body mass (mg)
1500
4294
600
Maturation attained at age (days)
±50
±40
±21 35
Start of cocoon production (days)
±55
±24
Cocoon production (per worm per day)
0.35
1.3
1.1
Same as E. fetida
Incubation period (days)
±23
±16.6
18.7
Hatching success in water (%) 73 50
63.4
90.5
Mean number of hatchlings ( per cocoon)
2.7
3.3
Number of hatchlings from one cocoon
1-9
1-5
1-3
1-12

22. Earthworm anatomy

23. Earthworms belong to the phylum “Annelida” (Latin meaning “little rings”)
Body is made of about segments.
Setae or bristles present on the earthworm body segments help them to anchor and control their movement
Digestive system is comprised of pharynx, esophagus, crop, gizzard and intestine.

25. Earthworm possesses a closed circulatory system.
Aortic arches, dorsal blood vessels, ventral blood vessels are the most important vessel to carry the blood supply.
Respiration takes place through earthworm skin by diffusion.
Moist or damp soil is important for its survival.
Earthworms are hermaphrodites, but need a mate to reproduce.
Cocoon i.e. “fertilized eggs” develop in to young worms

26. Due to their anatomy, earthworms play a major role in enriching and improving soil quality.
Earthworms create tunnels in soil by burrowing, helping in soil aeration, water and nutrient movement.
Organic part from decaying vegetation, plants take long period of time to degrade.
Earthworms feed on these materials and convert them in to more bio-available form as their “casting”.

27. Salient feature for vermicomposting bin maintenance
Optimum temperature: C.
Moisture content: 70-90%
Pile height: minimum 50 cm height, earthworm start consuming in a relative narrow layer of cm.

28. Ambient Temperature (28-300C) Incubation period: 60-90 days
Incubation Procedure
Earthworms
Proper moisture
Ambient Temperature (28-300C)
Hand sorting, Mixing
Vegetable waste
Drying & Sieveing
Dose: 10 worm/kg
Incubation period: days
9/19/2018

29. Suitable material for vermicomposing : cow manure, pig slurry, rice straw, activated sludge, paper sludge etc.
During the process of incubation, the substrate undergoes two phases namely destabilization and stabilization.
Under destabilization, hydrolysis takes place, whereas, under stabilization, mineralization takes place.