Get Free Competition Exam Notes and Jobs Detail by Email. Submit Your Email Address by filling below form

                Name :      Email :     

Friday, 23 March 2012

List of agricultural machinery


Traction and power

  • Tractor
  • Tracked tractor / Caterpillar tractor

Soil cultivation

  • Cultivator
  • Cultipacker
  • Chisel plow
  • Mulch tiller
  • Harrow
  1. Spike harrow
  2. Drag harrow
  3. Disk harrow
    • Plow (or plough)
    • Power tiller / Rotary tiller / Rototiller
    • Spading machine
    • Subsoiler
    • Two-wheel tractor
    • Stone picker ( picker)
    • Rock windrower (rock rake)
    • Rotavator
    • Destoner
    • Bedtiller
    • Ridger
    • Roller

Planting
  • Broadcast seeder (alternately: broadcast spreader or fertilizer spreader)
  • Planter (farm implement)
  • Plastic mulch layer
  • Potato planter
  • Seed drill
  • Air seeder
  • Precision drill
  • Transplanter
  • Rice transplanter

Fertilizing & Pest Control

  • Fertilizer spreader, see broadcast seeder
  • Terragator
  • Liquid manure/slurry spreader (slurry tanker)
  • Manure spreader
  • Sprayer
  • Slurry agitator

Irrigation

  • Center pivot irrigation
  • Drip irrigation
  • Hydroponics

Produce sorter

  • Weight sorter
  • Color sorter
  • Blemish sorter
  • Diameter sorter
  • Shape sorter
  • Density Sorter
  • Internal/taste sorter

Harvesting / post-harvest
  • Baler
  • Beet harvester
  • Beet cleaner loader
  • Bean harvester
  • Cane harvester
  • Cart
  • Carrot harvester
  • Chaser bin
  • Combine harvester
  • Conveyor belt
  • Corn harvester
  • Cotton picker
  • Cradle (grain)
  • Fanning mill
  • Farm truck
  • Flail
  • Forage harvester (or silage harvester)
  • Gleaner
  • Grain cleaner
  • Grain dryer
  • Gravity wagon
  • Haulm topper
  • Haulout transporter
  • Mower
  • Over-the-row mechanical harvester for harvesting apples
  • Potato spinner/digger
  • Potato harvester
  • Rake
  • Reaper
  • Reaper-binder
  • Rice huller
  • Scythe
  • Sickle
  • Silage trailer
  • Sugarcane harvester
  • Swather
  • Thresher
  • Tractor
  • Wagon
  • Winnower

Hay making
  • Bale mover
  • Bale wrapper
  • Baler and Big Baler
  • Conditioner
  • Hay rake
  • Hay tedder
  • Mower
  • Loader wagon, self-loading wagon – used in Europe, but not common in USA
  • Bale lifter
  • Topper

Loading
  • Backhoe/backhoe loader
  • Front end loader
  • Skid-steer loader

Milking

  • Bulk tank
  • Milking machine
  • Milking pipeline

Other
  • Allen Scythe
  • Grain auger
  • Feed grinder
  • Grain cart
  • Conveyor analyzer
  • Chillcuring
  • Shear Grab
  • Trailer
  • Power link box
  • Transport box
  • Bale trailer
  • Bale spike
  • Livestock trailer
  • Tractor mounted forklift
  • Buckrake
  • Bale splitter
  • Diet feeder
  • Hedge cutter, see flail mower
  • Post driver
  • Yard scraper

Obsolete farm machinery

Steam-powered:

  • Stationary steam engine
  • Portable engine
  • Traction engine
    1. Agricultural engine
    2. Ploughing engine
    3. Steam tractor
      • Reaper-binder
·        Flail
      • Hog oiler
      • Reaper
      • Winnowing machine/Winnowing-fan
      • Threshing machine
      • Drag harrow

Agricultural machinery


History
Hand tools

The first person to turn from the hunting and gathering lifestyle to farming probably did so by using his bare hands, and perhaps some sticks or stones. Tools such as knives, scythes, and wooden plows were eventually developed, and dominated agriculture for thousands of years. During this time, almost everyone worked in agriculture, because each family could barely raise enough food for themselves with the limited technology of the day.
The Industrial Revolution

With the coming of the Industrial Revolution and the development of more complicated machines, farming methods took a great leap forward. Instead of harvesting grain by hand with a sharp blade, wheeled machines cut a continuous swath. Instead of threshing the grain by beating it with sticks, threshing machines separated the seeds from the heads and stalks.
Steam power

Power for agricultural machinery was originally supplied by horses or other domesticated animals. With the invention of steam power came the portable engine, and later the traction engine, a multipurpose, mobile energy source that was the ground-crawling cousin to the steam locomotive. Agricultural steam engines took over the heavy pulling work of horses, and were also equipped with a pulley that could power stationary machines via the use of a long belt. The steam-powered machines were low-powered by today's standards but, because of their size and their low gear ratios, they could provide a large drawbar pull. Their slow speed led farmers to comment that tractors had two speeds: "slow, and darn slow."
Internal combustion engines

The internal combustion engine; first the petrol engine, and later diesel engines; became the main source of power for the next generation of tractors. These engines also contributed to the development of the self-propelled, combined harvester and thresher, or combine harvester (also shortened to 'combine'). Instead of cutting the grain stalks and transporting them to a stationary threshing machine, these combines cut, threshed, and separated the grain while moving continuously through the field.
Types
Combines might have taken the harvesting job away from tractors, but tractors still do the majority of work on a modern farm. They are used to pull implements—machines that till the ground, plant seed, and perform other tasks.

Tillage implements prepare the soil for planting by loosening the soil and killing weeds or competing plants. The best-known is the plow, the ancient implement that was upgraded in 1838 by John Deere. Plows are now used less frequently in the U.S. than formerly, with offset disks used instead to turn over the soil, and chisels used to gain the depth needed to retain moisture.

The most common type of seeder is called a planter, and spaces seeds out equally in long rows, which are usually two to three feet apart. Some crops are planted by drills, which put out much more seed in rows less than a foot apart, blanketing the field with crops. Transplanters automate the task of transplanting seedlings to the field. With the widespread use of plastic mulch, plastic mulch layers, transplanters, and seeders lay down long rows of plastic, and plant through them automatically.

After planting, other implements can be used to cultivate weeds from between rows, or to spread fertilizer and pesticides. Hay balers can be used to tightly package grass or alfalfa into a storable form for the winter months.

Modern irrigation relies on machinery. Engines, pumps and other specialized gear provide water quickly and in high volumes to large areas of land. Similar types of equipment can be used to deliver fertilizers and pesticides.

Besides the tractor, other vehicles have been adapted for use in farming, including trucks, airplanes, and helicopters, such as for transporting crops and making equipment mobile, to aerial spraying and livestock herd management.
New technology and the future

The basic technology of agricultural machines has changed little in the last century. Though modern harvesters and planters may do a better job or be slightly tweaked from their predecessors, the US$250,000 combine of today still cuts, threshes, and separates grain in essentially the same way it has always been done. However, technology is changing the way that humans operate the machines, as computer monitoring systems, GPS locators, and self-steer programs allow the most advanced tractors and implements to be more precise and less wasteful in the use of fuel, seed, or fertilizer. In the foreseeable future, some agricultural machines will be capable of driving themselves, using GPS maps and electronic sensors. Even more esoteric are the new areas of nanotechnology and genetic engineering, where submicroscopic devices and biological processes, respectively, are being used as machines to perform agricultural tasks in unusual new ways.

Agriculture may be one of the oldest professions, but the development and use of machinery has made the job title of farmer a rarity. Instead of every person having to work to provide food for themselves, less than 2% of the U.S. population today works in agriculture, yet that 2% provides considerably more food than the other 98% can eat. It is estimated that at the turn of the 20th century, one farmer in the U.S. could feed 25 people, where today, that ratio is 1:130 (in a modern grain farm, a single farmer can produce cereal to feed over a thousand people). With continuing advances in agricultural machinery, the role of the farmer will become increasingly specialized and rare.


Agricultural engineering


Agricultural engineering is the engineering discipline that applies engineering science and technology to agricultural production and processing. Agricultural engineering combines the disciplines of animal biology, plant biology, and mechanical, civil, electrical and chemical engineering principles with a knowledge of agricultural principles.
Some of the specialties of agricultural engineers include:

  • design of agricultural machinery, equipment, and agricultural structures
  • internal combustion engines as applied to agricultural machinery
  • agricultural resource management (including land use and water use)
  • water management, conservation, and storage for crop irrigation and livestock production
  • surveying and land profiling
  • climatology and atmospheric science
  • soil management and conservation, including erosion and erosion control
  • seeding, tillage, harvesting, and processing of crops
  • livestock production, including poultry, fish, and dairy animals
  • waste management, including animal waste, agricultural residues, and fertilizer runoff
  • food engineering and the processing of agricultural products
  • basic principles of electricity, applied to electrical motors
  • physical and chemical properties of materials used in, or produced by, agricultural production
  • bioresource engineering, which uses machines on the molecular level to help the environment.

Wednesday, 28 December 2011

MAJOR SOIL GROUPS (Part-2)


Red soils (Acrisols)
Ancient crystalline and metamorphic rocks have given rise to red soils. These soils are found predominantly in the states of Andhra Pradesh, Tamil Nadu, Karnataka, Maharashtra, Orissa, Goa and in the northeastern states. They have limitations of soil depth, poor water and nutrient-holding capacity, excessive drainage, runoff and are generally poor in N, P, zinc (Zn), sulphur (S) and humus. Under good management, these soils can be used profitably for a variety of crops such as millets, rice, groundnut, maize, soybean, pigeon pea, green gram, jute, tea, cashew, cocoa, grapes, banana, papaya and mango.
Laterite and lateritic soils are deeply weathered soils with a high clay content, having low base and silica owing to pronounced leaching. They are generally found in Kerala, Tamil Nadu, Karnataka, Andhra Pradesh and the northeastern region, and occupy about 25 million ha. The major limitations posed by these soils include deficiency of P, potassium (K), calcium (Ca), Zn and boron (B), high acidity and toxicity of aluminum (Al) and manganese (Ma). The important crops grown on these soils are rice, banana, coconut, areca nut, cocoa, cashew, coffee, tea and rubber.



Desert (arid) soils (Arenosols, Calcisols and Gypsisols)
Desert soils constitute the soils with negligible vegetation in both hot and cold regimes. They cover an area of about 29 million ha. The sandy material results in poor profile development under arid conditions. Water deficiency is the major constraint in cultivating these soils. A gypsic horizon is common in extremely arid areas such as Bikaner and Jaisalmer in Rajasthan. These soils are very prone to wind erosion.
Forest and hill soils are found at high as well as low elevations where rainfall is sufficiently high to support forest growth. Soil formation is governed mainly by the deposition of organic matter derived from the forest growth. Brown forest and Podzolic soils are common in the Northern Himalayas, while the Deccan Plateau forests have red and lateritic soils.
Saline and sodic soils occur under semi-arid conditions and occupy an area of 10 million ha. They are widely distributed in Rajasthan, Punjab, Haryana, Uttar Pradesh, Madhya Pradesh, Maharashtra and Gujarat. The sodic soils pose serious problems of a high sodium (Na) content, poor physical conditions and nutrient deficiency. Despite many limitations, once ameliorated using gypsum, sodic soils are used successfully for growing rice followed by wheat.
Peaty and marshy soils are formed by plants growing in the humid regions under permanently waterlogged conditions. They are found in Kerala, Orissa, West Bengal (Sundarbans) and along the South-East coast of Tamil Nadu. Where properly drained and fertilized, these soils often produce a very good rice crop.

MAJOR SOIL GROUPS (Part-1)


The great diversity in landforms, geological formations and climate conditions in India has resulted in a large variety of soils. Apart from a few soil orders (Andisols and Spodosols), all the major soils of the world are represented in India. Broadly, Indian soils consist of eight major groups, of which four are of agricultural importance: alluvial soils, black soils, red soils and lateritic soils. The four other broad soil groups that occur fairly extensively in India are: saline and sodic soils, desert soils, forest and hill soils, and peaty and marshy soils. These soil groups are related closely to the geographical character and the climate of the regions in which they occur.
Alluvial soils constitute the largest and most important soil group of India and contribute most to the agricultural wealth of the country. The soils are derived from the deposition of silt by the numerous river systems. They cover about 75 million ha in the Indo-Gangetic Plains (IGP) and Brahmaputra Valley and are distributed in the states of Punjab, Haryana, Uttaranchal, Uttar Pradesh, Bihar, West Bengal, Assam and the coastal regions of India. These soils are deficient in nitrogen (N), phosphorus and organic matter. Generally, alluvial soils range from near neutral to slightly alkaline in reaction. A wide variety of crops is grown in these soils.
Black soils are very dark and have a very high clay content. They have a high moisture retention capacity. They become extremely hard on drying and sticky on wetting. Hence, they are very difficult to cultivate and manage. These soils cover an area of about 74 million ha, mainly in the central, western and southern states of India. They are inherently very fertile. Under rainfed conditions, they are used for growing cotton, millets, soybean, sorghum, pigeon pea, etc. Under irrigated conditions, they can be used for a variety of other crops, such as sugar cane, wheat, tobacco and citrus crops.

AGRO-ECOLOGICAL ZONES

Agriculture is highly dependent on soils and climate. The ever-increasing need for food to support the growing population in the country demands a systematic appraisal of its soil and climate resources in order to prepare effective land-use plans. India has a variety of landscapes and climate conditions and this is reflected in the development of different soils and types of vegetation. Based on 50 years of climate data and an up-to-date soil database, the country has been divided into 20 agro-ecological zones (AEZs), Each AEZ is as uniform as possible in terms of physiography, climate, length of growing period and soil type for macrolevel land-use planning and effective transfer of technology.
Visit Website
Related Posts Plugin for WordPress, Blogger...