Rice-clam culture
Clams grow naturally in many rice paddies and rural people have traditionally harvested them. This was true until chemical use in rice paddies resulted in the elimination of these clams in many areas. Intentional culturing of clams simply adds one extra step to the traditional clam harvesting -the seeding of clams.
From work with farmers in Quirino province, it was found that:
· Clam culture in rice serves as a buffer against unforeseen crop losses due to flooding or diseases like tungro.
· Clam production serves as a source of additional income (in 1 hectare paddy the average yield was 226 kg marketable clams valued at P1,800/ha.)
· In addition to extra income, the clams serve as a source of protein and minerals for the farmer's family.
PROCEDURE:
1. 20-25 days after planting, increase the irrigation water in the paddies to the maximum tolerable depth proportionate to the rice plant (approximately 5 cm depth). If the crop needs weeding, the rotary weeder can be used before irrigation.
Increase the irrigation water in the paddies
2. Let the water stand for 2 days to soften the soil and to neutralize sold toxicity or pesticide residues.
Let the water stand for 2 days
3. On the third day, drain the water and replace it with fresh irrigation water to the depth mentioned above.
Drain the water and replace it with fresh irrigation water
4. Evenly broadcast baby clams along the rice furrows. Seeding should be done in every other furrow.
Evenly broadcast baby
5. Harvest the clams as soon as they reach the desired marketable size (size of the new P50 coin) or just before harvesting the rice.
Harvest the clams
Note:
· Avoid using chemical insecticides; as a substitute, use botanicals.
· Don't introduce carp into the paddies seeded with clams. Carp eat clams.
· Faster growth of clams is attained when fields are fertilized with organic materials.
· Medium- to long-maturing rice varieties should be used in clam-rice culture. This allows the clams to stay longer in the paddy field.
· Rice-clam system is best suited to areas where there is a continuous supply of water.
Rice-fish culture
Before the advent of modern farming practices, freshwater fish, such as catfish (Clarias sp.) and mudfish (Channa striate) grew abundantly in rice field paddies in Asia. These fish occurred naturally without being cultured by farmers. The indiscriminate use of chemicals for protection from pests in rice has largely reduced their populations.
In rice-fish culture, it is possible to produce freshwater fish like nile tilapia (Oreochromis niloticus) and carp (Cyprinus carpio) with catfish and mudfish along with a high rice yield.
Rice-fish culture
1. TRENCH CONSTRUCTION
· Begin construction before the onset of the rainy season.
· For tilapia, mudfish and catfish, the trench is 1 1/2-2 m wide and 1 m deep or 10% of the rice field area.
· For tilapia, mudfish and catfish, the trench is 1 1/2-2 m wide and 1 m deep or 10% of the rice field area.
Notes on Rice-Fish Trenches:
1. Raise peripheral dikes of the rice-fish field.
2. Locate the trench at the lower end of the field.
3. The bamboo outlet and inlet pipes should be at least 3 inches in diameter.
2. Locate the trench at the lower end of the field.
3. The bamboo outlet and inlet pipes should be at least 3 inches in diameter.
· The water that falls from the inlet pipes provides aeration to the trench.
· The outlet pipes are necessary for drainage to maintain the desired water level in the rice field.
· The outlet pipes are necessary for drainage to maintain the desired water level in the rice field.
4. Construct a small trench 30 cm wide and 30 cm deep. This will guide the fish to go to the trench.
5. For additional sources of income -- plant gabi, string beans and other suitable vegetables on the dikes. However, to minimize seepage, do not plant gabi where the pipes are installed.
5. For additional sources of income -- plant gabi, string beans and other suitable vegetables on the dikes. However, to minimize seepage, do not plant gabi where the pipes are installed.
2. FERTILIZATION OF THE TRENCH
· When there is enough water in the trench (from initial rains or from irrigation canal), apply any of the following organic fertilizers:
Chicken/Hog manure
|
Carabao/Cow manure
|
0.3 kg/sq.m fresh
|
0.5 kg/sq.m fresh
|
0.5 kg/sq.m dried
|
1.0 kg/sq.m dried
|
· Fertilize once a month or when the color of the water is no longer greenish. Greenish water is indicative that there is sufficient natural food (plankton) in the trench.
· Method of application
- Broadcast the manure after the construction of the trench (basal application).
- Place the manure in a sack. Submerge it in the trench 15-20 cm below the water level.
- You may also dump the manure in one corner of the trench.
3. STOCKING
· Stock the trench with Tilapia fingerlings (3-5 9) 15 days after the application of manure at the following rate:
- 1 fingerling/sq.m - no supplemental feeding (10,000/ha)
- 2 fingerlings/sq.m - with supplemental feeding (20,000/ha)
- 2 fingerlings/sq.m - with supplemental feeding (20,000/ha)
· If polyculture is practiced, the stocking rate should be:
- Tilapia - 75%-85%
- Carp - 10%-15%
- Catfish/Mudfish - 5%-10%
- Carp - 10%-15%
- Catfish/Mudfish - 5%-10%
4. LAND PREPARATION AND TRANSPLANTING
· During the onset of the rains, plow and harrow the land thoroughly. Transplant seedlings 1 day after the last harrowing.
· Maintain at least 1 inch water depth.
5. FERTILIZATION OF THE RICE FIELD
· Incorporate manure into the soil at the last harrowing.
- Chicken/Hog manure 2-3 kg./10M²
- Carabao/Cow manure 3-4kg./10M²
- Carabao/Cow manure 3-4kg./10M²
· At this point, also apply the recommended basal N for the rice crop.
6. OPENING THE DIKE
· One month after transplanting, make 3 openings in the dike to allow the fish from the trench to enter the rice field.
· Maintain the water level at 10-15 cm and increase it to 20-25 cm after the maximum tillering stage.
7. HARVESTING
· By the time the rice crop is ready for harvesting, so are some of the fish.
· Harvest only the big fish (50-60 9 or heavier). Extend the culture period of the smaller ones for the next rice cropping.
SUPPLEMENTAL FEEDING (OPTIONAL)
a) Rice bran- 80%
Ipil-ipil- 20%
Ipil-ipil- 20%
b) Rice bran - 65%
Ipil-ipil meal - 20%
Molasses/Golden
Snails (ground) - 15%
Ipil-ipil meal - 20%
Molasses/Golden
Snails (ground) - 15%
Supplemental feeding
Feeding Method
1. Add a little water to the feed ingredients and ball it.
2. Place the balled feeds in a feeding tray made of fish net.
3. Tie the feeding tray to a pole and submerge it in water (see illustration).
2. Place the balled feeds in a feeding tray made of fish net.
3. Tie the feeding tray to a pole and submerge it in water (see illustration).
Rate and Frequency of Feeding
· Determine the consumption of the fish per feeding by actual observation. First month 1-2 handfuls for 100 fish per day. Adjust the amount accordingly.
· Feed twice a day, morning and afternoon if necessary.
Notes:
1. For a single crop of rice, extend the culture of the small fish after the harvest by utilizing the whole field if water is still available.
2. Establish a tilapia and carp hatchery pond (3 m x 5 m) in addition to the trench to maintain a breeding stock of quality fingerlings for future use.
3. Catfish and mudfish are migratory. To keep them in the rice paddy/trench, they should be provided with a continuous supply of feeds. Tilapia fingerlings serve as feeds for catfish and mudfish, as do slaughter house by-products (pieces of skin) and crushed golden snail. Plant kangkong or gabi (taro) around the trench. This may help to discourage the fish from leaving the trench.
Rice-pig-fish culture
The traditional Chinese farming practice of pig and fish raising within the rice field is now spreading throughout the Philippines and Southeast Asia in general. In addition to supplementing income and improving nutrition through pig and fish culture within the rice field, rice-pig-fish culture maximizes land use by integrating three farm enterprises.
Design 1. The pig pen is constructed on top of the dikes near the trench. The floor should be sloping towards the trench and preferably be made of a soil-cement mix or concrete. A pipe is necessary to convey the waste matter into the bench.
Design 2. The entire pig pen is over the trench. The floor is made of bamboo slats spaced just enough to allow manure to fall directly into the trench but not too wide for the feet of the pigs to be injured.
BASIC STEPS IN ESTABLISHING THE SYSTEM:
1. Trench construction
Establish the trench at the lower end of the rice field. The minimum trench area requirement should range from 70-80 sq.m/pig. The water depth is 60-100 cm. The rice field area is 500 sq.m. Inlet and outlet pipes should also be installed.
2. Location of the pig pen
The pig pen should be near or over the trench. Typically, the pig pen is 1 m x 1.5 m for each pig.
3. Stocking
Fish:
Stock the trench with fish when there is enough water from the irrigation canal or from other sources.
Stocking rate:
Monoculture: one (1) fish/m² (average weight 3-5g) or 10,000fingerlings/ha.
Polyculture:
Tilapia nilotica - 75-85% (average weight 3-5 9)
Common carp - 10-15% (average weight 3-59)
Catfish/mudfish - 5-10% (average weight 1-29)
Tilapia nilotica - 75-85% (average weight 3-5 9)
Common carp - 10-15% (average weight 3-59)
Catfish/mudfish - 5-10% (average weight 1-29)
Pig:
Stock weanling -- 8-10 kg. in the pig pen.
Stock weanling -- 8-10 kg. in the pig pen.
4. Dike construction
Construct the dikes after plowing the rice field. The size of the dikes is 1 m wide at the base and 40-50 cm at the top. The height of the dikes should be 75-80 cm. Install the inlet and outlet pipes.
5. Land preparation
Plow the rice growing area at the onset of the rainy season to provide ample time for the construction of dikes.
6. Fertilization of the rice field and transplanting
a. For the first rice crop in a 500 m² rice field apply the following inorganic fertilizer (depending on the fertility and kind of soil)
Urea --5-10 kg
14-14-14 -- 3- 5 kg
14-14-14 -- 3- 5 kg
Reduce the rate of fertilizer application for the succeeding rice crop.
b. Allow some of the manure to flow to the rice field.
c. Transplant after thorough land preparation and fertilization.
c. Transplant after thorough land preparation and fertilization.
7. Opening the dikes
a. One month after transplanting, make 3-4 openings in the dikes in the trench to allow the fish to move into the rice field and forage for feed.
b. Maintain the water level at 10-15 cm and increase it to 20-25 cm after the maximum tillering stage.
8. Harvesting
a. Fish
Harvest the bigger-sized fish after 120-150days by draining the trench. Extend the culture period of the small fish to the next rice crop.
b. Pig
Sell the pig after 4-5 months.
c. Scrape out the decomposed organic waste and use as fertilizer for the rice crop.
NOTE:
Establish a tilapia and common carp hatchery pond (3m x 5m) to maintain a breeding stock of quality fingerlings for future use.
Vegetable-duck-fish culture (Tinola garden)
Tinola garden, as the name implies, is a type of garden where major ingredients in the preparation of tinola (a kind of poultry or fish soup with vegetables) are found in a 200 sq.m area.
Vegetable-duck-fish culture
BASIC COMPONENTS:
a. Duck raising for meat and/or eggs
b. Mini-fishpond
c. Vegetable growing
b. Mini-fishpond
c. Vegetable growing
This vegetable-duck-fish culture is actually a modification of the original mini-fishpond operation. This technology, however, optimizes land use by planting vegetables on the dikes, fence and the construction of trellis over the mini-pond. Depending on the preferences of the farmer, dikes could be planted with different vegetables and crops (e.g., leaf, fruit, root or legumes) and areas along the fence and trellis with any climbing vegetables.
ADVANTAGES:
Some of the advantages of this tinola garden are the following:
· increase in quantity and variety of food for home consumption
· ensures fresh supply of poultry meat and eggs, fish and vegetables
· ensures fresh supply of poultry meat and eggs, fish and vegetables
· practical for those farmers whose land area is less than 1.0 hectare and adopting the ricefish culture.
NOTES ON INDIVIDUAL COMPONENTS:
A. Vegetables
· On the trellis and fence -- squash, patola and other climbing vegetables.
· After the construction of pond dikes, the trellis could be constructed and planting of varieties of crops could immediately follow.
B. Mini-fishpond
· The dikes should be at least 1 m high, 1/2 m wide on the top and 1 m wide at the base.
· Water inside the pond must not be more than 1/2 m (to minimize fish losses).
· Recommended fish for stocking is Tilapia (Tilapia nilotica) and common carp (Cyprinus carpio) at the rate of 3 fingerlings/sq.m.
· Low-cost feeds may include rice bran, crushed snails and kitchen refuse.
Note: Refer to technology paper on Rice-Fish Culture for feeding and other management techniques.
C. Duck-Raising
Shed house (4 m x 1 m) made of low-cost and locally available materials (e.g., bamboo, ipilipil, madre de cacao, cogon, nipa, etc.) located in a 25 sq.m area in one section of the pond.
· Feeding troughs and waterers using old jeep or truck tires, clay pots or old cooking utensils.
· Stock: 8-12 heads (any species, depending on the farmer).
· Feeds may consist of rice bran, crushed banana trunk, crushed snails, kitchen refuse, kangkong, etc. Feeding is done twice a day.
Note: For more detailed information on duck raising, please see the technology paper on Backyard Duck Raising for Meat and Eggs.
Care and management of mini-ponds
The secret of success in growing fish in mini-ponds is proper care of the fish and management of the pond. Good pond management and care of the fish means faster growth and more fish for the family. The major points to remember are the following:
1. POND CONSTRUCTION
· Establish the mini-pond near a water source such as streams, springs, irrigation canals or manually operated pumps (pitcher pump), etc., which is free from flooding and with good drainage.
· The soil at the bottom and side of the minipond must be well packed to minimize seepage. If the soil is sandy or porous, line it with a mixture of carabao or cow dung, clay soil and cement.
· Plant grasses on the banks to prevent soil erosion. Grasses that grow fast and spread rapidly are ideal for this purpose.
· Put screens on the inlet and overflow pipes to prevent the entrance of predators and at the same- time to keep the fish from escaping.
Care and management of mini-ponds
2. WATER—QUALITY, DEPTH AND TEMPERATURE
· Water is of vital importance in raising fish. Always make sure that it is free from toxic substances, of the right temperature and the proper volume (depth). However, the warmwater fish do not require a constant supply of a large volume of fresh water. Most freshwater fish can be raised with water temperature ranging from 20°C - 40°C.
· The ideal water temperature ranges from 25°C - 30°C. In order to maintain the right temperature, plant leguminous trees like ipil-ipil (Leucaena leucocephala), katuray (Sesbania grandiflora), madre de cacao (Gliricidia septum) and Dapdap (Erythina) on two sides of the mini-pond, about 1.5 m - 2 m from the bank. Orient the planting of trees on the east-west direction to allow enough sunlight into the pond. The leaf litter also serves to improve aquatic life.
· Occasionally, the water in the pond becomes turbid and muddy. To check the turbidity of water apply lime at the rate of 1 tbsp/sq.m. Dissolve the lime water and sprinkle it over the pond.
· Maintain water depth at 1 m so that the sun's rays can penetrate the water and induce the growth of plankton (natural fish food). Production of plankton decreases as water depth increases. In shallow water (.5 m), the water temperature easily gets high during summer. High temperature retards fish growth.
· Avoid letting the water out from the pond to prevent the fertilizers and plankton from flowing out.
· Drain the pond once a year. Keep it dry for a period of 2-3 weeks to aerate the soil.
3. POND FERTILIZATION
Fertilize the pond
Any kind of animal manure can be used
· The production of algae and microorganisms in the mini-pond is the most important task for the low-cost production of fish. Fertilize the pond at least twice a month for the water to remain greenish. Green color indicates that the water has plenty of small plants and microorganisms which serve as nutritious food for the fish.
· Any kind of animal manure can be used. However, chicken manure makes a better fertilizer. Apply .5-1 kg chicken manure/m. The manure can be placed directly in one corner of the pond or put in a burlap sack and submerged 20 cm below the water surface. Never broadcast the manure on the surface as this, in turn, will reduce sunlight entry into the water, resulting in poor plankton growth.
· Dried leaves of leguminous trees can also be used to fertilize the pond. Put the leaves in porous bags and submerge in water 20 cm below the surface. One to two sacks of dried leaves can help fertilize the mini-pond. Dried rice straw can also be dumped directly in one corner of the pond. Occasional broadcasting of green leaves of leguminous trees (smallleaf varieties such as Calliandra, Leucaena, etc.) is also very helpful and promotes aquatic life.
· If a combination of organic and inorganic fertilizer is desired, 500 9 of organic fertilizer and 10 9 of inorganic fertilizer (preferably urea or 16-20-0)/m water can be applied to produce good results.
· On soils or water that are acidic, lime must be added. It can be broadcast on the bottom of the pond or put in a porous bag. Tie the bag to prevent it from submerging into the bottom of the pond. If lime is not available, it can be substituted by aged wood ash (not fresh ash or ash from paper).
4. FINGERLINGS
Stock only high-quality fingerlings. Secure your fingerlings from reliable hatcheries.
5. FEEDS AND FEEDING
· For faster growth, fish should be given supplemental feeds. A diet consisting of 20-30% ground ipil-ipil leaves or Azolla and 70-80% fine rice bran is recommended.
· When affordable, supplemental feeding of 100% fine rice bran is still the most economical (when natural food plankton in the mini-pond is abundant).
· Feed the fish twice a day, morning and afternoon.
· For a more efficient feeding, mash the feeds and place in a feeding tray made of fish net.
· The fish can also be fed with green leaves of kangkong, sweet potato, Azolla, kitchen leftovers, boiled sweet potato, cassava, gabi, crushed golden snails and white ants (termites).
· Surplus tilapia fingerlings (fresh) can be crushed and mixed with fine rice bran. This diet is very nutritious.
· Other cheap methods of feeding fish are:
- Hanging a lighted lamp over the center of the pond. At night, insects are attracted to the light and hover around it. The insects will fall into the pond where the fish can eat them.
- Feeding the fish with maggots (small worms). To produce maggots, hang pieces of meat or dead animals on a pole 2-3 ft above the water surface. Flies and other insects will lay their eggs on the meat or dead animals. After 2-3 days, maggots will come out and fall into the water.
6. CONTROL OF OVERPOPULATION
Overpopulation of fish is one of the problems in raising fish (tilapia) in mini-ponds. To obtain good yields of harvestable or marketable size of fish, population control is necessary. Any of the following methods may be used:
· Scooping the fry with a fine net early in the morning and late in the afternoon. The fries swim at the edges of the pond at this time of the day.
· Introducing predators into the pond such as mudfish (dalag) and catfish (hito) at 2% of the total stocking rate. To prevent predators from preying on the original stock, the size of the predators must be smaller than the original stock and should weigh less than one gram.
7. HARVESTING
· After 4-5 months, the bigger fish can already be harvested. Catch them with a hook and line using earthworms or golden snails as bait or use a sweep net.
· Harvest only enough fish for the family to consume.
· To ensure a continuous supply of fish for the family, replace the number of fish harvested immediately by collecting fingerlings from the breeding/hatchery pond.
Backyard poultry project using compost litter system
Backyard poultry project using compost litter system
With the high cost of producing imported breeds of birds for meat and eggs, the current trend for farm households is to revive the traditional family backyard poultry project using local and upgraded birds. These local breeds survive the adverse conditions found in the rural areas.
By using improved feeds and management practices, these local and upgraded birds can provide at least 130-200 eggs and extra poultry meat throughout the year for the family. These birds can be allowed to search for feed on the range or in confinement using a low-cost poultry compost litter system, practiced by some farmers in Cavite, Philippines. This system can sustain 6 hens and 1 rooster or 3 hens, 30 chicks and 1 rooster for at least 3 - 4 months. The compost litter is then removed and used as organic fertilizer and a new batch of farmyard manure is added. Production of a small flock in the backyard can help fill the family food requirements for eggs and meat, provide extra family income and utilize the manure as an excellent organic fertilizer.
BREEDS AND BREEDING:
The farm family should properly select an upgraded rooster (Cantonese, New Hampshire, Plymouth Rock breeds) and hens/layers.
Other poultry birds, like Muscovy duck. native or Pateros ducks, Peking duck, geese and pigeons are hardy and can also be raised under backyard conditions. They do not require elaborate housing and can subsist on inexpensive feeds.
HOUSING REQUIREMENTS:
Construct the house using local materials to minimize expenses, (cogon/nipa for roof, bamboo or used fish nets for siding' end ipil-ipil/madre de cacao as posts). The house should be located in a dry, well-drained area. Perch racks, roosts, nests, feed hoppers and waterers made of low-cost materials should also be provided.
The house should not be less than 2.0 m in height with a floor area of 3 m x 3 m. The house should be fenced; or if the hens are raised with chicks, they can be raised in a separate open house.
Before constructing the house, dig a pit in the floor 1/2 m deep, extending the length of the house (3 m) and 2 m wide. Once the building is completed, the pit should be filled with fresh manure of cattle, carabao or goat. Keep the manure moist for one week (to encourage the growth of worms and maggots as feed for the chickens) and then place the upgraded/native birds in the poultry house. While scratching the ground, the birds will be eating as well as hastening the composting process.
FEEDS AND FEEDING:
The family should provide extra feed supplements, like kitchen refuse, fish entrails, corn/sorghum, ipil-ipil leaves and others. Clean, potable water should be always available.
Home Made Chicken Ration
· 4 parts yellow corn, broken rice (binlid) or sorghum. Boiled gabi, fresh ubi, camote or cassava (bitter type should be boiled) can also be substituted.
· 1.5 parts rice bran (darak). Dried azolla or filter cake (from sugar mills) can replace rice bran.
· 1 part dried fish meal or 2 parts fresh fish/golden snail
· 1.5 parts cope/oil meal
· 0.5 part ground sitao/mongo (mung)/patani (lima bean)/soybean/kadios (pigeon pea) seeds
· 0.5 part dried ipil-ipil leaves
· 1 tbsp salt
· 1 handful powdered oyster shell/agricultural lime
Note: Double the recommended amounts if ingredients are not in dry form.
Other Low-cost Poultry Feeds
Carbohydrate Sources
|
Protein Sources
|
- Bananas
|
- Azolla
|
- Gabi
|
- Earthworms
|
- Ubi
|
- Filter cake (dried and powdered)
|
- Cassava
|
- Kitchen leftovers
|
- Camote
|
- Mole crickets
|
- Spoiled papayas
|
- Sorghum
|
- Rice bran
|
- Fish fingerlings
|
- Crushed golden snails
| |
- Termites
| |
- Tadpoles
| |
- Fly maggots
|
HEALTH MANAGEMENT:
Regular immunizations against Avian Pest, Fowl Pox and Fowl Cholera must be followed. A regular schedule of deworming, according to local conditions, must also be followed.
OTHER MANAGEMENT PRACTICES:
Other management practices like brooding, rearing the chicks, culling and selection and record-keeping should be practiced.
Backyard piggery project
Although demand for pork in many areas is high, the rising cost of production discourages many small farmers from attempting to raise swine on a small scale. The use of commercial feeds is one of the main reasons for high production costs. Purchased feeds can constitute 60-80% of total expenses. Once an animal is sold, the amount of return received, after paying the feed bill, is often too low to purchase another animal and sustain the cycle of production. Therefore, for farmers with little capital to invest, an alternative mode of production must be advocated. This alternative includes the utilization of low-cost materials and feeds available within the farm. Of particular importance is the potential to reduce feed costs.
BREEDS AND BREEDING:
Upgraded cross-breed animals are recommended.
Housing requirement
FEEDS AND FEEDING:
1. Low-cost Feeds
Commercial feeds, while complete and usually available, are costly, thus driving up the cost of production for a swine project. However, a variety of non-conventional or traditional foodstuffs can be utilized to provide low-cost feeds to swine.
Below is a list of common on-farm resources which can be used as carbohydrate and protein sources and several ration formulas (with Crude Protein percentage) using some of the following feed stuffs:
Carbohydrate Sources
|
Protein Sources (% Crude Protein)
| ||
Coconut oil meal (sepal)
|
3
|
Brewer's spent grain (15.4)
|
2
|
Rice middlings
|
1 or 4
|
Copra meal (19.42)
|
2
|
Rice bran
|
2
|
Cowpea (33.89)
|
4
|
Banana trunks
|
3
|
Fish meal (53.44)
|
2
|
Sweet potato (leaves, vine end tuber)
|
2
|
Jackbean (25.75)
|
4
|
Cassava ([eaves end tuber)
|
2
|
Pigeon pea (20.46)
|
4
|
Taro (leaves, stem and tuber)
|
1 or 2
|
Mung bean (22.66)
|
4
|
Kangkong
|
1
|
Peanut oil meal (43.65)
|
2
|
Ulasiman
|
2
|
African snail (45.91)
|
1
|
Banana (peers end rice fruit)
|
2
|
Soybean meal (soya) (43.70)
|
2
|
Banana (raw fruit)
|
1
|
Rice bean (tapilan) (17.42)
|
2
|
Papaya (green)
|
1
|
Velvet bean (24.02)
|
4
|
Papaya (ripe)
|
2
|
Hyacinth bean (3.6)
|
1
|
Muskmelon
|
2
|
Leucaena leaves (17.52)
|
2
|
Jackfruit
|
1
| ||
Pineapple
|
2
| ||
Elephant yam (pongapong)
|
1
| ||
Yam bean (singkamas)
|
2
| ||
Ubi peelings
|
1
| ||
Leafy vegetables
|
1 or 2
| ||
Water lily
|
1
| ||
1 -- Needs cooking.
2 -- Can be given fresh or as is.
3 -- Should be mixed with rice bran or commercial feeds.
4 -- Needs soaking.
LOW-COST SWINE RATIONS
Ration 1
|
Parts by Wt.
|
Rice bran
|
60 kg
|
Yellow corn
|
10
|
Coconut (bagasse)
|
10
|
Leucaena leaf meal
|
5
|
Rice middlings
|
5
|
---------
| |
100 kg
| |
Crude Protein
|
12.881%
|
Ration 2
|
Parts by Wt.
|
Rice bran
|
80 kg
|
Gabi tuber/Cassava
|
20
|
Japanese/Golden Snail
|
10
|
Ground yellow corn
|
10
|
Leucaena leaf meal
|
10
|
---------
| |
100 kg
| |
Crude Protein
|
14.91%
|
Ration 3
|
Parts by Wt.
|
Rice bran
|
80 kg
|
Leucaena leaf meal
|
15
|
Rice middlings
|
5
|
-----------
| |
100 kg
| |
Crude Protein
|
14.9175%
|
Ration 4
|
Parts by Wt.
|
Rice bran
|
60 kg
|
Swamp cabbage leaves
|
30
|
Yellow corn
|
5
|
Coconut bagasse
|
5
|
---------
| |
100 kg
| |
Crude Protein
|
9.965%
|
Ration 5
|
Parts by Wt.
|
Rice bran
|
60 kg
|
Banana trunks (chopped finely)
|
30
|
Leucaena leaf meal
|
10
|
----------
| |
100 kg
| |
Crude Protein
|
10.591%
|
Ration 6
|
Parts by Wt.
|
Dry camote
|
57 kg
|
Rice bran
|
30
|
Copra meal
|
4
|
Fish meal
|
5
|
Soybean oil meal
|
5
|
----------
| |
100 kg
| |
Crude Protein
|
10.6%
|
Ration 7
|
Parts by Wt.
|
Cassava or sweet potato
|
25 kg
|
Rice bran
|
50
|
Copra meal
|
25
|
-----------
| |
1 00 kg
| |
Crude Protein |
11.45%
|
2. Proper Feeding
a. Leftover food scraps from the house should be cooked to kill germs and remove toxin present in the foodstuff.
b. Unconsumed feeds in the troughs should be discarded before giving new feed to the animals.
3. How to Prepare Feeds for Swine
a. Chop all ingredients into small pieces.
b. Boil hard ingredients first (i.e., pongapong, green papaya, water lily, etc.).
c. When soft, add other ingredients (i.e., kangkong, leftover food, etc.).
d. Cook until done.
e. Cool.
f. Add a pinch of salt before feeding to the animals. These cooked feeds should be mixed - with rice bran when fed to the animals.
4. Alternative Feeding Management for a Fattener
a. During the first 2 months, feed piglets with commercial feeds (if the necessary ingredients to make a homemade, nutritious feeds are not available) to promote and boost growth.
b. In the second month, gradually substitute commercial starter ration with grower ration and begin slowly incorporating cooked supplemental feeds into the diet.
c. In the third month, one quarter of the ration can be replaced with supplemental, low-cost feeds previously listed.
d. At the fattening stage (4-6 months), one-half or more of the ration can be supplemental, lowcost feeds.
HEALTH MANAGEMENT:
1. Animals should be purchased from a reliable source in order to insure their hearth. Newly acquired animals should be isolated and observed for at least 2 weeks to determine their health status before introducing them into the pen area with other animals.
2. A regular schedule of vaccination should be followed to protect animals against swine diseases common in the area (i.e., hog cholera, etc.).
3. Animals should be regularly dewormed as needed or as local conditions dictate.
4. Improved sanitation ensures improved animal health:
a. Maintain clean pens.
b. Animals should be regularly bathed, especially during hot weather.
c. Excreta should be properly disposed, preferably composted in a pit or pile.
Backyard duck raising for meat and eggs
Backyard duck raising for meat and eggs
WHY RAISE DUCKS?
Ducks are one of the most practical, versatile and useful waterfowls to raise. Duck raising offers several benefits:
· Ducks are efficient producers of animal protein.
· Ducks provide both eggs and meat, for consumption or for sale.
· Ducks require limited space, simple shelter and minimal care.
· Ducks are resistant to diseases and thrive in harsh conditions.
· Ducks control harmful insects, unwanted aquatic weeds and golden snails.
· Duck manure is an excellent organic fertilizer.
· Ducks provide both eggs and meat, for consumption or for sale.
· Ducks require limited space, simple shelter and minimal care.
· Ducks are resistant to diseases and thrive in harsh conditions.
· Ducks control harmful insects, unwanted aquatic weeds and golden snails.
· Duck manure is an excellent organic fertilizer.
· Ducks eat aquatic plants, grasses, vegetable trimmings, golden snails, insects and farm byproducts. Thus, providing feed is not a problem.
WHAT BREED TO RAISE FOR MEAT AND EGGS:
The Muscovy is a multipurpose breed for meat and eggs. The most popular Muscovy ducks raised are the white and black types. They lay from 80-120 eggs/yr and produce an excellent quality meat.
The Khaki Campbell breed is more efficient for egg production as compared to other breeds. A single duck is capable of producing 250-350 eggs/yr.
HOUSING REQUIREMENTS:
Since ducks are small, a simple shed with one open side can provide adequate shelter. A 1 1/2 m x 5 m x 1 m high shelter can accommodate 40-50 adult ducks. To prevent the ducks from destroying vegetables and other crops, they should be confined in a fenced structure made from locally available materials.
Farm litter (e.g., rice straw) should be placed in the shed for laying and brooding purposes.
STARTING A BACKYARD PROJECT:
A beginner can start with 7 ducks -- one male (drake) and 6 female (ducklets). It is preferable to acquire ducks that are from 1-2 years of age.
FEEDS AND FEEDING:
Muscovy ducks are voracious eaters and eat practically anything they are fed. For maximum growth, ducks should be fed with natural, local feeds such as empty grains (rice), rice and corn bran, ipil-ipil leaves, golden snails, duck weed, Azolla, banana trunks, worms, etc. They should be fed three times a day and provided with fresh water always. Used tires or old cookings utensils can be used for waterers and feeders. Twenty-five ducks can be raised in a 1-hectare farm using onfarm feeds without commercial feeds.
HEALTH MANAGEMENT:
To prevent a disease outbreak, animals should be regularly vaccinated against common diseases (e.g., Newcastle, Fowl Pox or Fowl Cholera). Deworming and other health care practices, such as proper sanitation, correct feeding and proper care and management, must be strictly implemented to ensure a disease-free flock. New birds introduced into a flock should be quarantined to ensure that they are disease-free. Sick birds should also be isolated from healthy stock during treatment.
OTHER MANAGEMENT PRACTICES:
Hatching
Ducks start to lay eggs after reaching 6 months of age. One medium-size duck is capable of hatching 12-15 eggs during the 30-33 day incubation period. Layers are usually productive from 1218 months. At the end of that production period, layers should be culled and eaten or sold.
The fertility of eggs can be determined using a simple technique known as candling. Eggs should be candled (on the 15th day of incubation) in a dark room using at candle, lamp or flashlight. Fertile eggs reveal a small dark spot with a network of blood vessels branching out from it or the eggs appear dark. Infertile eggs are clear with the yolk appearing as a floating shadow. Do not throw away infertile eggs; they are delicious as well as nutritious and can be eaten or processed into salted or hard-boiled eggs to be sold for extra income.
Duckling Rearing
Young ducklings must be kept warm and dry. It is best to keep them out of water until they are 2 weeks old. However, they must have a constant supply of fresh drinking water. The ducklings should be fed fine rice bran and boiled rice. Cracked corn or rice should be fed to them after they are several weeks old.
It is very important to protect the ducklings from predators such as cats. dogs; rodents, birds, etc. One method of protecting the ducklings is to confine the hen and her brood in a covered pen each night until the ducklings are 6-8 weeks old.
Marketing
Meat-type birds are ready to be slaughtered, dressed and marketed at 5-6 months of age.
DUCK MANAGEMENT WITHIN A RICE SYSTEM:
Two pen/shelter design options are presented here:
The duck pen and shelter is constructed over the irrigation canal The floor is made of bamboo slats spaced so as to allow the droppings to fall into the water below, but not to trap and injure the ducks' feet. The floor should slope slightly to allow the eggs to collect on one side of the pen, thus facilitating daily egg collection. This design allows the duck droppings to fall directly into the water and be carried to the rice paddies through the irrigation canal. One disadvantage to this design, however, is the possible danger of housing the ducks directly over the water during colder times of the year
The duck pen and shelter
The other design places the shelter near, but not over, the irrigation canal. Cover the floor with 4-6 inches of dry bedding material i.e., rice straw. Remove the old bedding materials weekly and place them in a compost pit for future incorporation into the rice paddies as fertilizer.
The is shelter near, but not over, the irrigation canal
Ducks should be given adequate time to forage for their food. The ducks should be released from their house in the morning after they have laid their eggs (about 7:00 a.m.). The most important consideration is that the ducks be released at the same time every morning. If they are released at different times every day, the change can upset them, causing them to stop laying eggs and even begin to molt. They should be herded back to the pen about 5:30 in the afternoon. Giving them some feeds regularly at this time also trains them to return to their pen.
Ducks should be released onto the ricefields only at certain times:
- During plowing and harrowing
- After the tillering stage, but not during the flowering and heading stage of the ricecrop
- After the rice has been harvested and threshed.
When it is not possible to release the ducks into the ricefield, they should be taken to an area where no crops are grown. If no such area is available, the ducks can be fed in confinement.
Backyard carabao raising for draft and milk
Backyard carabao raising for draft and milk
The carabao (swamp-type buffalo) is a prized symbol of a farmer's wealth and is an integral component of Philippine agriculture. Millions of crop farmers rely on this animal as the main source of draft power for almost all farming operations despite the introduction of small power tillers. The carabao provides animal protein in the form of meat and milk; as well as hides and horns (which have many economic uses) and manure, a potential organic fertilizer for the farm.
Carabaos are also excellent potential sources of milk as they can produce 300 to 800 kilograms of milk during a lactation period of 180 to 300 days. Murrah crossbreeds can produce 42% more milk than the native caracows. Carabao milk has a higher nutritive value than cow's milk and can be easily used in the production of soft white cheese (kesong puti).
MANAGEMENT PRACTICES AT BACKYARD LEVEL:
A. Breeds and Breedings
1. Carabao breeds commonly found in the Philippines:
a. Draft type -- Philippine carabao and Thailand buffalo
b. Dairy type -- Murrah and Nili/ravi
b. Dairy type -- Murrah and Nili/ravi
2. Selection of breeding animals
Selection of breeding animals
a. Caracow/caraheifer to be selected should be 3-4 years old, with well-developed udders, large and uniformly shaped teats, possess a docile and good dairy temperament, angular form, be more lean than meaty and be an offspring of a known good milker.
b. Carabull or carasteer to be selected should be 4 to 6 years old, healthy and vigorous, possess a masculine character, medium to short neck, massive with a blocky conformation and have a heavy and welldeveloped body. Additionally, the animal should have well-developed fore and hindquarters, be powerful, low-set and alert and of good temperament. The male animals are best used for work purposes.
c. Judicious culling and selection of animals must be practiced in order to maintain the best animals in a herd.
3. Breeding:
a. Natural breeding is the common practice using the best carabull available to mate caracow/caraheifer. This is considered the best due to the silent heat (30-56%) among caracows.
b. Artificial insemination (A.l.), however, is considered the easiest and cheapest method of improving local animals using prostaglandin hormone end frozen semen, if Al technician and equipment are accessible in your area.
4. Reasons to crossbreed native caracow (Philippine carabao) with selected Indian Murrah buffalo bull (for more comparative information see Table 1).
a. The offspring is bigger, taller and more active.
b. Crossbreed caracows produce more milk (42% more) than native caracows.
c. Crossbreed offspring have a higher growth rate (30-40%) than native carabaos.
d. Crossbreed animals possess better draft ability in upland condition.
Note: Based on research studies, crossbreed caracows in the third generation (5/8 Murrah and 3/8 Philippine carabao), when compared with pure breed animals, have comparable levels of milk production.
B. Housing Requirements
1. Provide a dry, clean and well-ventilated shed made of nipa, bamboo and/or wood. It is advisable to cement the floor to facilitate cleaning. Trees can be grown around the shed, to serve as a windbreak and provide extra shade during the summer months. Animals should always be kept in dry stalls in the evening and under the shed during the summer months.
2. Construct a compost or manure pit nearby for disposal of left-over feed litter and manure. A carabao produces 10.8 kg. manure/day or 6,853 kg. in 360 days (1.22% N. 0.85% P and 0.79% K)
Housing
C. Feeds and Feeding Management
1. Carabaos are usually raised in semi-confinement, which involves tethering the animal for 810 hours/day on native pasture.
2. Low-cost feeds for carabao
a. For light to medium work (4 to 6 hours/day).
b. Before and after work, carabaos should receive plenty of clean drinking water. When in a heated condition, however, they should be allowed to cool off before watering. Work carabaos may lick salt in a box or may receive salt in their feed, (for example, one handful/head, three times a week.)
3. Supplementation of urea-molasses-mineral block to diet of rice straw or summer grazing pasture is sufficient to maintain lightweight.
4. Clean feed, water and a source of salt should tee constantly provided to animals in the pen/stall area.
D. Health Management
1. Immunization against hemorrhagic septicemia and foot and mouth disease should be administered every six months or at least once a year. Animals should be dewormed against liver fluke and intestinal worms as a preventive measure et least once a year using herbal treatments (betel nut & ipil-ipil) or commercial dewormers.
2. Control lice and other external parasites at least 34 times a year. During summer the common practice by farmers of shaving the body hair of their carabao helps to control external parasites.
3. Because carabaos have few sweat glands and little hair, the animals should be regularly bathed to keep the animal cool during summer months (especially draft animals).
E. Other Management Practices
1. Carabao as Draft Animal
Farmers use carabao as draft in their farming system for the following reasons:
a. It is an affordable, low-cost technology and the investment can pay for itself in a short time period.
b. The carabao and harness are available locally and maintenance can be conducted by the farmers.
c. After a carabao can no longer serve as a draft animal, it can become a source of carabao meat and meat by-products. Carabao meat (carabeef) has 46% less cholesterol than beef.
A well-trained carabao works efficiently and will demand a higher price. Ideally, farmers should raise their own draft carabao or purchase them while they are still young. Young carabao (about 2 years old) are easier to tame and train.
The draft capacity of an animal increases with its weight. For example, a 300 kg. carabull can pull a moldboard plow or harrow with a 30 kg. draft requirement for 8 hours. But, if the animal is made to pull 130 kg. it will only work for 3 to 4 hours before tiring. The animal must be allowed to assume a natural pace to produce an extended, rather than a concentrated effort.
To prevent abortion, a pregnant caracow should only be made to work on a limited basis. especially during the first 6 months of pregnancy. A newly calved caracow should not be used for draft until the calf reaches 3 to 4 months of age.
Tips on training carabao for work
Training carabao for work
a. Touch the animal constantly.
b. Slowly expose the animal to crowded places (i.e., along the side of the road) by riding its back.
c. Training can be done from 1 to 3 hours during cool periods of the day (i.e., early morning or late afternoon).
d. While leading the animal to pasture, place a well-fitted yoke with a smooth surface on the animal's neck and attach a sledge to train the animal to pull.
e. Then, train the carabao to pull the harrow on loose ground for an easy start.
f. Finally, train the animal to pull the plow on a plowed field during cod periods until the animal gets used to pulling heavy loads.
2. Carabao as Source of Milk
Although the carabao is a slow milk producer, its mliking capacity can be improved through proper management, systematic breeding and proper milking techniques. Local carabaos and upgrades should be tapped as a major source of milk and milk byproducts. A caracow can produce 2 to 2.5 liters of milk daily by hand-milking.
Milking Procedures and Management:
Caracows should be milked in a clean, dry place. The caracow should be cleaned to remove dirt that may fall into the milking can. The calf is allowed to stay with the caracow for 2 to 4 weeks after birth and then separated in the evening to prevent the calf from suckling. After milking, the calf can stay with the caracow.
The most common milking method is hand-milking.
1. The animal is tied to protect the milker.
2. The milker should wash his/her hands with soap and water.
3. Prepare a clean milking bucket, properly covered with a clean cloth.
4. Wash and massage the udder and teats with a clean cloth soaked in warm water.
5. Strip the teat to check if the milk is clean (organo/eptic test) and if no abnormalities are observed.
6. If nothing abnormal is observed, milk the animal until the milk flow stops.
7. If possible, the animal should be milked at the same time everyday by the same person. Concentrate should be provided at milking time (helps to increase milk output).
8. Pasteurize the milk collected from the caracow. Do not attempt to add wafer or en adulterant as it will spoil the quality of milk. Heat the milk up to 145 F on a double boiler. When it starts boiling, continue to stir the milk with a spoon while heating for 30 minutes. Then cool the milk by replacing the hot water with cool water for 30 minutes at about 42 F. Place the milk in a bottle. The milk is now ready for market or can be stored in a refrigerator for 3-4 days.
Comparative Gross Composition of Carabao's Milk, Buffalo's Milk and Cow's Milk
MILK
| |||
Properties
|
Carabao (%)
|
Buffalo (%)
|
Cow (%)
|
Fat
|
9.65
|
7.31
|
3.80
|
Protein
|
5.26
|
5.74
|
3.40
|
Lactose
|
5.29
|
4.89
|
4.85
|
ASL
|
0.95
|
0.81
|
0.75
|
LOW-COST FEEDS FOR CARABAOS:
1. For light to medium work (carabao working for 4 to 6 hours/day)
Feeding Ration Recommended for en average-sized Carabao
RATION (Kg)
| |||||
1
|
2
|
3
|
4
|
5
| |
Rice bran
|
3
|
3
|
4
|
2
|
3
|
Copra meal
|
2
|
2
|
-
|
-
|
-
|
Napier grass
|
25
|
35
|
25
|
-
|
-
|
Peanut hay
|
5
|
-
|
-
|
-
|
-
|
Ground corn
|
-
|
2
|
-
|
-
|
-
|
Soy bean (soilage)
|
-
|
-
|
15
|
20
|
-
|
Sugar cane tops
|
-
|
-
|
-
|
25
|
20
|
TOTAL
|
35
|
42
|
44
|
34
|
43
|
2. Hard Work -- Carabao employed whole day for plowing/cart work/pulling heavy logs in the forest with only 2 hours rest at noon.
Feeding Ration Recommended for en average-sized Carabao
RATION (Kg)
| |||||
1
|
2
|
3
|
4
|
5
| |
Rice bran
|
6
|
4
|
7
|
5
|
5
|
Copra meal
|
3
|
3
|
-
|
4
|
2
|
Napier grass
|
35
|
25
|
20
|
-
|
-
|
Peanut hay
|
-
|
5
|
-
|
-
|
-
|
Soybean (soilage)
|
-
|
-
|
20
|
-
|
25
|
Sugar cane tops
|
-
|
-
|
-
|
35
|
20
|
TOTAL
|
44
|
37
|
47
|
44
|
42
|
SOME IMPORTANT INFORMATION ABOUT CARABAO AND ITS UPGRADES
Philippine Carabao (PC) (Draft)
|
Murrah Buffalo(Dairy)
|
Carabao Buffalo* Philippine Carabao
| |
Body Weight
| |||
- at calving
|
27 kg.
|
29 kg.
|
34 kg.
|
- at six months
|
110 kg.
|
134 kg.
|
130 kg.
|
-yearling weighs
|
141 kg.
|
241 kg.
|
208 kg.
|
- two years old
|
272 kg.
|
306 kg.
|
340 kg.
|
- three years old
|
480.8 - 515 kg.
|
525-625 kg.
|
557.36-609.62 kg.
|
Milk production - liter per lactation
|
528 (8 months)
|
1,149 (10 months)
|
1,032 (10 months)
|
Age at first fertile mating
|
859-885 days (2 years, 4 months-2 years, 6 months)
|
1,275 days (3-1/2 year) months)
|
844 days (2 years, 3
|
Age at 1st calving
|
1,342 days (3 years, 7 months)
|
1,582 days (4 years, 4 months)
|
1,178 days (3 years, 3 months)
|
Estrus cycle
|
21 days
|
21 days
|
21 days
|
Estrus period (watch for silent heat)
|
5 to 36 hours
|
24 to 72 hours
|
24 hours
|
- onset of estrus
|
dawn/early morning
|
dawn/early morning
|
dawn
|
Ovulation time
|
15 hours (after end of estrus)
|
11 hours (after cessation of estrus)
|
14 hours (after end of estrus)
|
Gestation period
|
320 to 325 days
|
310 days
|
316 days
|
Calving intervals
|
1 1/2 year
|
1 1/2 year
|
1 1/2 year
|
Breeding season*
|
August to January
|
August to January
|
August to January
|
Calving months
|
July to September
|
July to September
|
July to September
|
Post-partum breeding
|
60 days
|
133.82 ± 78.93
|
133.82 ± 78.93
|
Incidence of twinning
|
2:10,000
|
-
|
-
|
* Breeding occurs any time of the year but more during the rainy season and cooler months.
Azolla meal for layers and broilers
Although most people think of Azolla as fertilizer, one way of beating the high cost of feeds for farm animals is by supplementing the animals' regular diets with Azolla. Drying, ensiling and other feed treatments using fresh Azolla are simple and effective ways to ensure that optimum benefits can be obtained from Azolla by farm animals.
Azolla meal for layers and broilers
MATERIALS NEEDED:
· freshly harvested azolla
· commercial layer or broiler rations
· trays with slits or perforated bottoms for drying Azolla
· commercial layer or broiler rations
· trays with slits or perforated bottoms for drying Azolla
· commercial grinder (gilingan) for grinding Azolla into powder or feed bag for holding Azolla during manual crushing
· empty motor oil can (1 liter) for measuring the ingredients.
Materials needed
PROCEDURE:
1. Harvest Azolla from the propagation pond. Wash thoroughly to remove soil and other residues. Do not use Azolla which has been exposed to pesticides.
Procedure
2. Place the Azolla on trays and sundry it for 3-7 days or until it-turns brown. Azolla is sufficiently dry when it crumbles when squeezed.
Place the Azolla on trays
3. Grind the dried Azolla to form a powder resembling coffee. If no grinder is available, place the dried Azolla in a feed bag and step on it until it is crushed.
Grind the dried Azolla
4. Combine the Azolla meal with commercial layer or broiler rations at a ratio of 1:9.
Combine the Azolla meal with commercial layer
Note: For growing native and upgraded chickens like Cantonese, Azolla meal can be given as a supplement to ordinary low-cost feeds.
SOURCE: UPLB, National Azolla Action Program
Azolla silage as feed for growing pigs
Aside from being used as green manure by farmers, Azolla can also be used as feed supplement for growing pigs. It has a crude protein content of 17-28% and contains amino acids, vitamins and trace minerals. Unlike ipil-ipil (Leucaena), Azolla has no toxic substance (mimosine).
When Azolla is ensiled, its moisture content is lowered to a manageable level, improving its nutritional value. When the silage is added to commercially available concentrate mixes, the resulting mixture easily meets the nutritional requirements of growing pigs.
Azolla silage as feed for growing pigs
The following materials are needed in preparing Azolla silage:
· net bags or sacks for drip-drying Azolla
· trays with slits or perforated bottoms for further drying
· empty kerosene and motor oil cans for measuring ingredients
· pails for storing the ensiled Azolla
· plastic sheets and rubber strips for sealing the pails.
· trays with slits or perforated bottoms for further drying
· empty kerosene and motor oil cans for measuring ingredients
· pails for storing the ensiled Azolla
· plastic sheets and rubber strips for sealing the pails.
PROCEDURE:
1. Collect Azolla from the propagation pond. Make sure the Azolla is free from soil and other debris by thoroughly washing it. Do not use Azolla which has been exposed to pesticides.
Collect Azolla from the propagation pond
2. Place the harvested Azolla in net begs or sacks and allow to drip for 2-3 hours.
Place the harvested Azolla in net begs
3. Transfer the dried Azolla to the trays to allow further drying and to provide good ventilation. Spread out the Azolla end turn over 2-3 times a day for even drying.
Transfer the dried Azolla to the trays
Azolla is dried from a moisture content of 95% to 65-70%*. Drying takes about 2 days during sunny weather and 3 days in cloudy weather.
TWO AZOLLA SILAGE FORMULATIONS:
Sillage 1
· Sillage 1 - 70% Azolla + 30% corn
Mix 1 kerosene can (balde) of dried Azolla, with 4 1/2 motor oil cans of corn. Place the mixture in a pail. (If possible, use plastic pails for storing ensiled Azolla. Pails made of tin will rust.) Use plastic sheets to cover the pails and rubber strips to tightly seal the container and keep oxygen out. Let the mixture ferment for at least 1 week.
· Silage 2 - 70% Azolla + 25% corn + 5% molasses
Silage 2
Mix 1 kerosene can of dried Azolla, with 4 motor oil cans of corn. Add 1/3 motor oil can of molasses. Follow the same succeeding procedures as in Silage.
Note: If corn is not available, other carbohydrate sources like rice bran. cassava meal, etc., can be used.
It is recommended that each pail of ensiled Azolla be enough for one feeding to minimize oxygen combining with the mixture when the cover is removed. Oxygen must be kept out to prevent the growth of mold and worms (maggots) in the mixture.
When, the Azolla silage is fed to growing pigs, it may be added to mixed grower ration (MUIR) or commercial grower mix (CGM)
Ensiled Azolla can be stored up to 2 months without affecting the nutritive value of the feedstuff, as long as the container is kept sealed. Once opened, the silage must be consumed within a week.
Amounts needed at 25 percent Azolla silage supplementation
Weight of Growing Pigs (kg)
|
Amount of Azolla Silage (kg)
|
Amount of MGR CGM (kg)
|
20 - 35
|
1.50 - 1.80
|
1.00
|
36 - 50
|
2.00 - 2.50
|
1.50
|
51 - 60
|
2.50 - 3.00
|
2.00
|
Amounts needed at 10 percent Azolla silage supplementation
Weight of Growing Pigs (kg)
|
Amount of Azolla Silage (kg)
|
Amount of MGR CGM (kg)
|
20 - 35
|
0.50 - 0.80
|
1.40
|
36 - 50
|
1.00
|
1.80
|
51 -60
|
1.00
|
2.25
|
SOURCE: National Azolla Action Program c/o Office of the Dean UPLB College of Agriculture
College, Laguna 3720
Multipurpose trees for the lowlands
Trees are an important component of the lowland ecosystem. They provide readily available firewood, poles and stakes and protect the field from strong winds. Trees also improve the microclimate of the farm and attract birds and other beneficial insects, thereby reducing insect infestation.
Multipurpose trees give additional incentive for cultivation. The leaves are excellent for green manure. They grow fast and coppice easily thus reducing the need to replant after every harvest.
There are different species of multipurpose trees. For lowland areas, however, they should be tolerant or moderately tolerant to occasional water logging.
Species of multipurpose trees for lowland areas (1)
Species of multipurpose trees for lowland areas (2)
Species of multipurpose trees for lowland areas (3)
Additional livestock feed resources
Additional livestock feed resources
The fact that the best land is devoted to food or cash crop production should not allow livestock production to be ruled out. Marginal lands can be used to pasture animals as well as to produce animal fodder in order to optimize scarce land resources. Farmers view livestock production not in competition with crops, but rather as a complementary farm operation which can convert crop residues and farm by-products not fit for human consumption or market into valuable animal products.
Increasing the supply and quality of livestock fodder has positive effects for the whole farm system, in addition to improving the health and productivity of the animals. Livestock are an integral component of the nutrient cycling system of a farm and directly or indirectly affect three aspects of nutrient cycling:
1. Nutrients are redistributed on the farm when they are brought up from deeper soil levels by trees whose leaves are fed to livestock.
2. Nutrient availability to plants is increased when crop residues and other feeds are converted to manure.
3. An increase in nitrogen supply is brought about when legume forage are grown and fed to the animals.
Therefore, there is a need to integrate livestock production into other farming components by harnessing marginal farm areas for the production of livestock resources.
GRASSES AND LEGUMINOUS TREES ALONG EARTHEN DIKES, IRRIGATION CANALS AND ROAD BANKS:
These areas often constitute the neglected and waste areas of the farm and are usually left to grasses and weeds such as cogon (Imperata cylindrica), talahib (Saccharum spontaneum), aguingay (Rottboella exaltata), amorseko (Chrysopogon aciculatus). Paddy dikes are usually repaired before planting the rice and once the rice is planted, they can serve as animal fodder sources of grasses and tree legumes. Napier grass (Pennisetum purpureum) on dikes, for example, can produce more than 1.5 kg dry matter (DM)/yr/linear m. Andropogon yielded 36.7 tons of DM/ha when planted along the dikes. Leguminous trees and shrubs can provide high protein fodder using species such as madre de cacao (Gliricidia septum), ipil-ipil (Leucaena leucocephala), Sesbania (Sesbania sesban) and others. Two-year old Gliricidia, for example, produced 5 kg DM/tree/yr of top quality fodder when planted 2 m apart.
Along the banks of roads and irrigation canals, Guinea grass (Panicum maximum) and Napier grow well. In waterlogged areas, Para grass (Panicum purpurescens) thrives well even when it is cut at 4-6 week intervals.
Grasses and legumes planted along earthen dikes, irrigation canals and road banks not only provide feed, but also help to control soil erosion.
INTENSIVE FEED GARDEN ALONG FARM BOUNDARIES:
Other often-neglected areas are farm boundaries. Some farmers install live fences and barbed wire to control passage of humans and stray animals. Farmers in Batangas and Cavite (Philippines) maximize the use of farm boundaries by planting hedgerows of intensive feed gardens (IFG) as potential sources of fodder for their livestock. They interplant Leucaena and Gliricidia with Napier grass and/or other grasses. This system provides the livestock with nutritious fodder throughout the year. During the wet season (June- December), came feed on fresh grasses and legumes, while during the dry season (January-May), they eat green fodder from leguminous trees supplemented with hay (dried rice straw or corn stover).
In Bali, Indonesia, most farmers use a Three-strata Forage System (TSFS), a technology of planting and harvesting three different strata (one composed of a grass or ground legume, another of a shrub legume and a third of a fodder tree) to provide a source of livestock fodder throughout the year. The first stratum consists of grasses (Cenchrus ciliaris, Urochloa mosambisensis, Panicum maximum) and ground legumes (Centrosema pubescens, Stylosanthes hamata, S. scabra) which provide fodder during the wet season. The second stratum consists of shrub legumes (Gliricidia, Leucaena, Acacia vellosa) which provide fodder during the wet and dry seasons. The third stratum consists of fodder trees (Ficus poacellie, Lannea corromandilica, Hibiscus tilliaceus) which provide fodder during the dry season.
Intensive feed garden along farm boundaries
Note: Fodder grasses should be cut after leaf dew dries in the morning (between 9:00 and 10:00) as a precaution against possible liver fluke infection.
Planting Arrangement of the Grasses Legume Shrubs and Fooder trees in the TSPS.
The botanical composition of the forage offered to cattle will vary according to:
Season:
|
First Stratum
|
Second Stratum
|
Third Stratum
|
Total
|
During the first 3 years
| ||||
Wet Season
|
65 % +
|
35 % +
|
0 =
|
100 %
|
Dry Season
|
35%
|
65 %
|
0
|
100 %
|
During the 4th and succeeding years
| ||||
Wet Season
|
65 %
|
25 %
|
10 %
|
100 %
|
Dry Season
|
35 %
|
40 %
|
25 %
|
100 %
|
The TSFS offers many advantages to a small farmer with livestock. The utilization of small parcels of land is maximized by combining cash or food crops with animal fodder species. For example, the plot in this diagram is one-quarter hectare (2500 sq.m) and comprises three distinct areas and sources of production: a 1,600-sq.m core area planted to traditional cash or food crops (the crop residues can also be fed to livestock); a 900-sq.m peripheral area subdivided into 45 sq.m areas planted to improved grasses and legumes; and the 200 m circumference area planted to fodder trees and shrub legumes which form a hedgerow fence around the area.
Livestock, an income-generating farm component, are integrated into the farm using a cut-and carry and stall feeding system. With the increased supply of higher quality fodder, 12 % increases in growth rates have been documented and the carrying capacity of a 1 hectare area can be increased to 4 animals/ha. With the combination of the species within the three strata, forage production can increase by as much as 48%. Through the use of drought-resistant species, forage is available throughout the year. The grasses, shrubs and trees also help reduce water run-off, thus reducing soil erosion. Lastly, the legume shrubs and trees can produce 1 1/2 tons of firewood/yr.
HAY PRODUCTION AND STORAGE:
The mandala or straw stack is a prominent symbol in rice-growing communities. Rice straw is the by-product of rice after threshing and is a potential feed source for carabaos during the summer lean months. It is rich in carbohydrates and is available when pasture grasses are affected by drought or when all of the farm area are planted to field crops.
Farmers in the rice-producing areas of the Philippines store large quantities of rice straw after the rice harvest by sundrying and storing them as bales in a covered barn or as loose hay in the oval-shaped, compact mandala, supported in the middle by a bamboo pole firmly anchored in the ground. The mandala is located in an elevated spot of the farm near to where the livestock are kept. The upper portion should be covered to protect the straw from the rain. Rice straw can be stored longer if its moisture content (MC) is between 13-14%. But, if the MC is above 20%, heat may be produced, causing spontaneous combustion and possible fire or inducing mold growth which reduces the feed value of the straw. An average-sized mandala contains about 1,200 kg DM and has 3.3% crude protein (PCARRD, 1978).
Hay production and storage
In India, the straw stack is located in one corner of a field or on the roof of the animal shed. The posts are made of cut stones and large- boulders are utilized for the foundation.
Straw stack
In other parts of India, another storage system is used. Large stones are used to build a foundation. Then, bamboo poles are laid upon the stones close to each other as a slatted floor. Rice straw, pearl millet and sorghum straw are tightly pressed and compacted into the space. The materials must be tightly compacted to prevent exposure to air which can cause spoilage. The top tapers to the sides and is covered with canvas or plastic sheets to protect it from the rain.
Plastic sheet
Another dried roughage which can be stored is corn stover, the portion of the plant left in the field once the ears have been harvested. The whole plant is left in the field should be stored and protected from rain, otherwise it mildews disintegrates, making it unfit for feed.
OTHER CROP RESIDUES:
1. Sugarcane (Saccharum officinarum)
In sugarcane plantations which use many carabaos, sugarcane tops comprise their only source of daily feed during the milling season. Instead of drying and burning the cane leaves and tops in the field, they should be collected,' cried and stored for future use. Whether sugarcane tops are dried or green, they are palatable and relished by carabaos and cattle. They contain a large amount of digestible carbohydrates in sugar form.
2. Pineapple (Ananas saliva)
In areas where pineapples are grown as a cash crop, the leaves and damaged fruit can be used as animal fodder. After the plants have borne fruit for 2 years, they are removed to make way for new crops. The plants are gathered and the spiny portion removed and cut into 2-3 inch pieces before given to the animals.
3. Peanut (Arachis hypogaea)
Peanuts not only produce quality, nutritious food legume! but can yield up to 8-10 T fodder/ha. Once the peanuts have been harvested, the vine can be fed as peanut hay. The nutritive value is high because of its protein content (10.8-11.9%), as well as its potassium, vitamin A and calcium contents. An additional advantage is its high palatability. For best
· results, the vines should be dried well and protected from rain and dew.
4. "Miramais" (tentatively identified as Sorghum bicolor)
Farmers in Pangasinan province (Philippines) use a portion of their farm to cultivate this indigenous grass, which is similar in appearance to corn. It is a hardy plant which grows well in well-drained, fertile soils and can withstand drought, pests and diseases. It is usually planted before the end of the dry season (October-November) and is cut 30 cm above the ground before it develops a tassel. The stems and leaves are fed and are relished by animals. The plant will develop a tiller and ratoon to produce more forage.
Shelterbelts for rice farms
Shelterbelts are windbreaks, specifically rows of trees planted to serve as protection from excessively strong winds. Shelterbelts modify a farm's microclimate and reduce crop damage from the force of wind. Depending upon the height, placement and orientation of the shelterbelt along a certain stretch, the shelterbelt can also:
· decrease temperature and relative humidity
· decrease plant and soil water loss (evapotranspiration) and the entry of hot air to the farm (advection)
· increase the rate of carbon dioxide replenishment.
The most beneficial effect of shelterbelts is the reduction of mechanical injury, e.g., leaf defoliation and lodging in areas experiencing high wind speeds. There are reports showing that shelterbelts increase plant growth and yield.
The effectiveness of shelterbelts depends essentially on the interaction of two factors:
1. Height of shelterbelt: Higher shelterbelts protect a longer stretch of crops on the leeward side (the side protected by the shelterbelt).
2. Porosity: The degree of perforation is usually dependent on foliage qualities such as leaf arrangements, sizes and shapes. More perforated barriers allow less turbulent winds to blow and protect an even longer stretch on the leeward side.
Porosity
2. Orientation. To effectively protect crops, 2-3 rows of shelterbelts should be oriented perpendicular to the predominant direction of strong or typhoon winds.
Orientation
3. Placement. Shelterbelts may be placed near farm boundaries, in areas not used for crop production, or near farm-house boundaries.
Unless rice bunds are widened to accommodate a row of shelterbelts, it would not be ideal to place shelterbelts in the bunds because:
- of waterlogging problems
- there will be competition among crops for water, light and nutrients
- it may be an alternate host to rice insect pests and diseases
- it may hamper field operations.