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Sci-Tech Dictionary:

baler

(′bāl·ər)

(mechanical engineering) A machine which takes large quantities of raw or finished materials and binds them with rope or metal straps or wires into a large package.

 
 
How Products are Made: How is a hay baler made?

Background

The term "hay baler" refers to a particular piece of agricultural equipment used to harvest hay. Hay includes grasses and other plants called legumes. Timothy Grass, alfalfa, and clover are common hay crops. These crops, used as animal feed, are cut with a mowing machine when they are about 18 inches (46 cm) tall and still green. The mowing machine cuts and crimps the forage and discharges it into a 4-feet (1.2 m) wide windrow. This crimping process breaks the stems and makes the hay more palatable to cattle. A hayrake is used to turn the hay over so that the windrow can dry completely. The baler gathers the cut hay from the windrow and compresses it into square- or round-shaped bales for easy transportation and storage.

Most hay is stored as bales, with small square bales weighing 40-70 pounds (18-32 kg) and large round bales weighing 750-2,000 pounds (341-908 kg). Small bales must be protected from rain and snow in a dry place such as a barn or hay shed. The large round bales can be left outside because the rain will run off the sides, instead of soaking through and rotting the hay. Small bales can be fed by hand into feed bunks or hay feeders. The larger round bales are handled with a tractor equipped with a "bale mover," a spear-like attachment that pierces the bale and allows the hydraulic loader to lift and transport it to the feeder.

History

During the late 1800s and early 1900s, farming was changing dramatically with the introduction of many new machines. Until that time, hay had been stored loose in the upper story of the barn, or "haymow," where it took up considerable space. By compressing the hay, or baling it, more hay could be stored in the same amount of space. One of the first balers was powered by horses walking on an inclined treadmill. As the leather and wood treadmill belt moved with each step of the horse, it turned a shaft that operated a chain drive. The chain drive, through a variety of sprockets, drove a plunger into the baler, which compressed the hay. Hay was hauled to the baler from the field in wagons, and then forked into the bale chamber by hand. Wooden blocks were dropped into the chamber when the bale reached the right size. Wire or twine was then threaded around the bale and tied by hand. As technology improved, the steam traction engine replaced the horse, and the internal combustion tractor eventually replaced the steam engine. By the 1930s, balers were attached to tractors, and they automatically picked up hay from the ground. Improvements in hydraulics allowed the introduction of the large round baler in the late 1960s. Companies such as John Deere, New Holland, and Hesston have continually refined the baler into a modern farm implement.

How It Works

Hay balers are pulled behind and powered by the tractor in the field. The baler has flotation tires, which reduce the damage to the hay stubble by distributing its weight over a larger area. Also connected to the tractor is the Power Takeoff Shaft (PTO), which transmits rotary power from the tractor to the baling mechanism. Along the sides of the hitch are the hydraulic hoses that operate the various controls on the baler using hydraulic pressure from the tractor. When operating the baler, the tractor pulls the baler pickup, a horizontal spool of moving steel teeth, in line with the windrow and engages the PTO drive.

Operation of a Small Square Baler

The hay enters the baler through the pickup, and the teeth gently rake the hay from the ground to prevent the loss of leaves and ingestion of rocks or debris into the baler. Directly behind the pickup is the compressor bar, which holds the hay in place so the auger can feed it into the bale chamber. The bale chamber contains a plunger that drives in and out, each time packing and compressing hay into the desired shape. The plunger also cuts the ends of the hay to make the bale an uniform size. The chamber feeds into a spring tension section that keeps the bale tightly compressed until enough hay has been processed to complete the bale. When the correct length of bale is achieved, a mechanism wraps the bale with two lengths of twine or wire and ties it securely. The twine is carried on spools and fed through two curved needles that are timed to miss the cycle of the plunger. After the twine is in place, a gear mechanism called a knotter ties the knot and cuts the twine free of the supply spool. All of this motion occurs in less than two seconds, and must be carefully timed to prevent interference with the continued operation of the rest of the baler. After it is tied, the bale is pushed down the bale chute and falls to the ground. Some balers have "kickers," or bale ejectors, which throw the bale onto a hay rack pulled behind the baler.

Operation of a Large Round Baler

Like the small baler, the large round baler uses a pickup to load the hay from the ground into the bale chamber. Here, how-ever, the hay is wrapped onto itself by six to eight long rubber belts that are 7 inches (18 cm) wide. As the hay is drawn into the machine, the bale becomes round and fills the bale chamber to capacity. The hay exerts force upon the belts, which is in turn monitored by the hydraulic system. Once a predetermined pressure is reached, a signal is transmitted to the tractor operator. The operator stops the forward movement of the baler, and the bale is automatically wrapped with twine or protective sheeting. After wrapping, the tension on the belts is released and the entire rear portion of the baler is opened by hydraulic cylinders. The bale then simply rolls out onto the ground. The baler is pulled ahead, the rear closes, and baling resumes. The entire process can be operated from the tractor, and bale ejection takes from 15 to 45 seconds.

Raw Materials

Balers are constructed primarily of structural and sheet steel. This steel can be in bar stock, sheets, or in rolls. Hydraulic cylinders, pumps, wheels and tires, belts, and other components are purchased from suppliers and shipped to the baler assembly plant. The belts are made of nylon and polyester, a material similar to tires. All raw materials are carefully specified by the engineering staff after extensive testing and research. Many portions of the baler arrive as subassemblies, put together by divisions of the baler manufacturer or by independent suppliers.

The Manufacturing
Process

Cutting the sheet metal

  • The outer skin, covers, and shields of the baler are punched or blanked out of sheet steel in a large punch press or by laser cutter. The sheet metal can be taken directly from the roll, or precut into flat sheets as needed. Punch presses operate by forcing a hardened steel punch through the material into a hardened die with up to 200 tons of force. This shears the metal to size, and the rapid stroke of the punch press allows many parts to be produced per hour. More intricate shapes and low-volume parts are cut using an industrial laser to burn through the metal in a preprogrammed pattern. In spite of being slower than the punch press, the laser reduces material waste by arranging the part shapes to most effectively utilize the sheet size. Another advantage of the laser cutter is that it requires practically no set up, which means it can create different-sized parts without physically adapting the machine. This is important, as one machine can then produce hundreds of different parts, in any random order, and provide them to the rest of the manufacturing process as needed.

Cutting the bar stock

  • Bar stock steel that is used for frames, shafts, arms, and other structural parts is cut using a band saw. These saws have many toothed cutting blades driven over two large wheels. The wheels rotate and move the blade continuously to cut through the bar. Bar stock can be round, square, rectangular, solid or hollow, plus many other shapes specific to the desired application. After cutting to length, holes and slots are drilled, punched, or milled into the parts as needed. Structural parts are usually fabricated close to the welding area to minimize time between operations.

Welding

  • Welding is performed primarily by robotic welders. These machines are operated by a computer that has been programmed to move the welding electrode wire through a specific range of motion. The robotic welder is very accurate and makes high-quality, repeatable welds. After the various components are clamped into a large welding fixture by the operator, the robot extends a short piece of welding wire from the welding gun. With the welding current turned off, it gently touches a computer sensor that accurately defines the exact position of the wire tip. Then, the robot touches the tip of the wire to each of the components in two or three places. All of this touching is actually transmitting data to the computer about the exact location of the components in reference to the desired location of the weld. Once complete, the computer program compensates slightly for any deviation from the exact position. The welding current is turned on and the wire is fed into the arc while the robot moves the gun along the joint. This insures that the welds will be exactly at the proper place and achieve the highest possible strength. It also prevents welding any misplaced or incorrect parts, reducing scrap and possible machine failures. In many critical applications, robotic welders can be more accurate than a human welder because of this type of programming.

Cleaning and painting

  • After welding, fabricated parts as well as shields and covers are cleaned and painted. Cleaning is accomplished by hot steam or solvents inside an enclosure. The paint is applied by dipping the parts into an electrostatic paint tank. These tanks are large enough to submerge an entire baler frame, typically 15 feet (4.5 m) long and 10 feet (3 m) wide. They contain 20,000-40,000 gallons (75,700-151,400 1) of paint. The paint is suspended in a water solution and charged with a negative electric charge. The parts are charged positive, and when the parts submerge into the solution, the electrical attraction of the two charges sticks the paint tightly to the metal. The parts are hoisted out of the tank and allowed to drip before they are placed into a drying oven. This drying oven heats the parts to approximately 365°F (185°C), which bakes the paint into a hard finish. Because balers are used and sometimes stored outside, a good finish is needed to protect the steel from rusting.

Assembly

  • After painting, the frame of the baler is placed onto a wheeled cart. This allows the baler to be moved and assembled at a variety of work stations, each adding specific components and performing quality checks during production. The hydraulics, pickup tines, bale tensioners, knotters, and subassemblies are bolted into place. Many design features create special hole patterns, tabs, pins, notches, and other forms to prevent the parts from being assembled in the wrong place or position. After assembly, the hydraulic systems are filled with oil, belt and chain tensions are adjusted, and the bearings greased. The baler then has the tire and wheel assemblies mounted and identifying decals and stickers attached. Since a baler can be a very dangerous machine, many warning labels are applied to caution operators to keep their hands away from the moving parts.

Inspection and adjustments

  • Finished balers are finally inspected and operated without hay to check the functionality of all the parts. Most are shipped by truck or railcar to dealers all over the world. A technician may be sent out to the field with the new baler to instruct the operator and make final adjustments. Often, changes in the hay crop will require occasional adjustment to the baler to produce quality bales.

Quality Control

During a production run, balers are closely inspected at various stages for proper function and durability. Whenever possible, features are designed into parts and processes to prevent incorrect parts and subassemblies from leaving the assembly line. Occasionally, a completed baler is taken from production for testing either by special test equipment or by actual field trials. Subassemblies can be tested and even destroyed without sacrificing the entire baler.

Data acquisition computers are used to record the test performance and, using Computer Aided Design (CAD) programs, offer engineering changes to improve performance. Like automobiles, balers have local service dealers that can notify customers of correct maintenance procedures and/or new features that may be retrofitted to existing balers.

The Future

Processing hay for animal feed has improved greatly in the past 20 years, primarily due to the advent of the large round baler. Even larger balers are on the market, but the round baler seems most popular at present. As the size and complexity of the machine increase, so does the cost. Custom balers, people who bale for resale, are a large portion of the new baler market, along with large corporate farms. These operators usually have the larger tractors to power big balers, and with improvements in hydraulics and bale wrapping, the large baler will probably be the standard for the next several years.

Where To Learn More

Bell, Brian. Farm Machinery, 3rd ed. Diamond Farm Book Publishers, 1989.

[Article by: Douglas E. Betts]


 
Columbia Encyclopedia: hay baler,
farm machine that packs and ties (or wraps in plastic) field-dried hay into bundles, called bales, for convenient handling, storage, and shipping. It ordinarily picks up hay that has been raked into rows (see rake)and packs and ties it into round or rectangular bales to be picked up by truck. Some modern balers include automatic stacking or loading devices. Very large bales are often stored in the field and moved with front-end loaders. Nearly all hay in the United States is baled.

Bibliography

See C. Culpin, Farm Machinery (12th ed. 1992).

 
Wikipedia: baler
This article describes the farm machinery. For the municipality in Aurora, Philippines, see Baler, Aurora.
A round baler
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A round baler

A baler is a piece of farm machinery that is used to compress a cut and raked crop (such as hay or straw) into bales and bind the bales with twine. There are several different types of balers that are commonly used. Balers are also used in the material recycling facilities, primarily for baling plastic, paper or cardboard for transport to a recycling facility.

Round baler

A round bale
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A round bale
Round baler in action
Enlarge
Round baler in action

The most frequently used type of baler is a round baler. It produces cylindrically shaped 'round' or 'rolled' bales. The hay is simply rolled up inside the baler using rubberized belts, fixed rollers, or a combination of rollers and belts. When the bale reaches a determined size, the twine or mesh wrap that binds the bale is wrapped around the outside but not knotted. The back of the baler is opened up and the bale is discharged. Variable chamber balers typically produce bales from 48 to 72 inches in diameter (about 180 cm) and up to 60 inches in width. The bales weigh from 1100 lb (500 kg) to 2200 lb (1000 kg).

Early round balers were sold by Allis Chalmers as the Roto Baler. These bales were roughly 16 inches in diameter and 48 inches wide. The concept was first pioneered by Ummo Luebbens as early as 1910. Introduced in 1947 and discontinued in 1960, Allis Chalmers was a pioneer in supplying machinery that would form cylindrical bales during a period where rectangular bales were most common.

The modern round baler was designed in 1972 by the Vermeer Company, which as of 2007 continues to produce them.[1][2]

Round bale handling and transport

Round bales can weigh a ton or more, and are well-suited for modern large scale farming operations such as a dairy with 200 or more cows. However, due to the ability for a round bale to roll away on a slope, they require special transport and moving equipment.

The most important tool for round bale handling is the bale spear or spike, which is usually mounted on the back of a tractor or the front of a skid-steer. It is inserted into the approximate center of the round bale, then lifted up and the bale is hauled away. Once at the destination, the round bale is set down, and the spear pulled out. Careful placement of the spear in the center is needed or the round bale can spin around and touch the ground while in transport, causing a loss of control.

Alternatively, a grapple fork may be used to lift and transport round bales. The grapple fork is a hydraulically driven implement attached to the end of a tractor's bucket loader. When the hydraulic cylinder is extended the fork clamps downwards towards the bucket, much like a closing hand. To move a round bale the tractor approaches the bale from the side and places the bucket underneath the bale. The fork is then clamped down across the top of the bale, and the bucket lifted with the bale in tow.

It is difficult to flip a round bale so that the flat surface is facing down and later flip it back up on edge, so transporting many round bales a long distance is a challenge. Flat-bed transport is difficult since the bales could roll off the truck bed going around curves and up hills. To prevent this, the flat-bed trailer is equipped with rounded guard-rails at either end, which prevent bales from rolling either forward or backward. Another solution for this is the saddle wagon, which has closely-spaced rounded saddles or support posts for round bales to sit in. The tall sides of each saddle, or the bale settling down in between posts, prevent the bales from rolling around while on the wagon.

Round bales can be directly used for feeding animals by placing it in a feeding area, tipping it over, removing the bale wrap, and placing a protective ring around the outside so that animals don't walk on hay that has been peeled off the outer perimeter of the bale. The baler's forming and compaction process can assist in unrolling a round bale, as it is often possible to unroll a round bale in a continuous flat strip.

Large rectangular baler

Large rectangular baler
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Large rectangular baler

Another type of baler in common use produces large rectangular bales, each bound with a half dozen or so strings of twine which are then knotted. Such bales are highly compacted and generally weigh somewhat more than round bales.

Rectangular bale handling and transport

Rectangular bales are easier to transport than round bales since there is little risk of the bale rolling off the back of a flatbed trailer. The rectangular shape also saves space and allows a complete solid slab of hay to be stacked up for transport.

They are well-suited for large scale livestock feedlot operations where the farmer does not produce any of their own livestock forage, and instead purchases all of it from someone else whose exclusive task is growing and baling hay.

Due to the huge rectangular shape, a large fork lift is more appropriate for lifting and moving the bales.

Small square baler

A small square baler
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A small square baler

A type of baler which is less common today in some places but which is still prevalent in many countries such as New Zealand and Australia to the exclusion of large bales produces small rectangular or 'square' bales. Each bale is about 15 in x 18 in x 38 in (38 x 46 x 96 cm). The bales are wrapped with two, three, or sometimes four strands of twine and knotted. The bales are light enough for a person to handle, about 45 lb (20 kg) to 60 lb (25 kg).

To form the bale, the hay in the windrow is lifted by tines in the baler's 'pickup'. The hay is then dragged or augered into a chamber that runs the length of one side of the baler. A combination plunger and knife moves back and forth in the front end of this chamber. The knife, positioned just ahead of the plunger, cuts off the hay at the spot where it enters the chamber from the pickup. The plunger rams the hay rearwards, compressing it into the bales. A measuring device measures the amount of hay that is being compressed and, at the appropriate length it triggers the mechanism (the knotter) that wraps the twine around the bale and ties it off. As the next bale is formed the tied one is driven out the rear of the baling chamber onto the ground or onto a special wagon hooked to the end of the baler. This process continues as long as there is material to be baled.

This form of bale is no longer much used in large-scale commercial agriculture because of the costs involved in handling many small bales. However, it enjoys some popularity in small-scale, low-mechanization agriculture. Besides using simpler machinery and being easy to handle, these small bales can also be used for insulation and building materials in straw-bale construction. Square bales will also generally weather better than round bales because a more much dense stack can be put up. Convenience is also a major factor in farmers deciding to continue putting up square bales, as they make feeding in confined areas (stables, barns, etc.) much easier.

Many of these older balers are still to be found on farms today, particularly in dry areas where bales can be left outside for long periods.

The automatic-baler for small square bales took on most of its present form in 1940. It was first manufactured by the New Holland Ag and it used a small petrol engine to provide operating power. It is based on a 1937 invention for a twine-tie baler with automatic pickup.

Wire balers

Bales prior to 1937 were manually wire-tied with two baling wires. Even earlier, the baler was a stationary implement, driven by power take-off (PTO) and belt, with the hay being brought to the baler and fed in by hand. The biggest change to this type of baler since 1940 is being powered by the tractor through its PTO, instead of by a built-in internal combustion engine.

Square/wire bale history

Pickup and handling methods

In the 1940s most farmers would bale hay in the field with a small tractor with 20 or less horsepower, and the tied bales would be dropped onto the ground as the baler moved through the field. Another team of workers with horses and a flatbed wagon with would come by and use a sharp metal hook to grab the bale and throw it up onto the wagon while an assistant stacks the bale, for transport to the barn.

A later time-saving innovation was to tow the flatbed wagon directly behind the baler, and the bale would be pushed up a ramp to a waiting attendant on the wagon. The attendant hooks the bale off the ramp and stacks it on the wagon, while waiting for the next bale to be produced.

Eventually as tractor horsepower increased, the thrower-baler became possible, which eliminates the need for someone to stand on the wagon and pick up the finished bales. The first thrower mechanism used two fast-moving friction belts to grab finished bales and throws them at an angle up in the air onto the bale wagon. The bale wagon was modified from a flatbed into a 3-sided skeleton frame open at the front, to act as a catcher's net for the thrown bales.

The next innovation of the thrower-baler as tractor horsepower further increased was the hydraulic tossing baler. This employs a flat pan behind the bale knotter. As bales advance out the back of the baler, they are pushed onto the pan one at a time. When the bale has moved fully onto the pan, the pan suddenly pops up, pushed by a large hydraulic cylinder, and tosses the bale up into the wagon like a catapult.

The pan-thrower method puts much less stress on the bales compared to the belt-thrower. The friction belts of the belt-thrower stress the twine and knots as they grip the bale, and would occasionally cause bales to break apart in the thrower or when the bales landed in the wagon.

New Holland has invented a machine named the "STACKCRUISER" , or referred to as a stacker. Small "square" bales are dropped by the baler with the strings facing outward, the stacker will drive up to the bales and it will pick it up and set it on a three bale wide table (the strings are now facing upwards). once three bales are on the table, the table lifts up and back causing the three bales to face strings to the side again, this happens 3 more times until there are 16 bales on the main table. this table will lift like the smaller one and the bales will be up against a vertical table. the machine will hold 160 bales (ten tiers), usually there will be cross-tiers near the center to keep the stack from swaying or colasping if any weight is applied to the top of the stack. The full load will be transported to a barn, the whole rear of the stacker will tilt upwards until it is vertical. there will be two pushers that will extend through the machine and hold the bottom of the stack from being pulled out from the stacker while it is driven out of the barn

Storage methods

Before electrification occurred in rural parts of the United States in the 1940s, some small dairy farms would have tractors but not electric power. Often just one neighbor who could afford a tractor would do all the baling for surrounding farmers still using horses.

To get the bales up into the hayloft, a pulley system ran on a track along the peak of the barn's hayloft. This track also stuck a few feet out the end of the loft, with a large access door under the track. On the bottom of the pulley system was a bale spear, which is pointed on the end and has retractable retention spikes.

A flatbed wagon would pull up next to the barn underneath the end of the track, the spear lowered down to the wagon, and speared into a single bale. The pulley rope would be used to manually lift the bale high up into the air until it could enter the mow through the door, then moved along the track into the barn and finally released for manual stacking in tight rows across the floor of the loft. As the stack filled the loft, the bales would be lifted higher and higher with the pulleys until the hay was stacked all the way up to the peak.

When electricity finally arrived, the bale spear, pulley and track system disappeared, replaced by long motorized bale conveyors known as hay elevators. A typical elevator is an open skeletal frame, with a chain that has dull 3-inch spikes every few feet along the chain to grab bales and drag them along. One elevator replaced the spear track and ran the entire length of the peak of the barn. A second elevator was either installed at a 30-degree slope on the side of the barn to lift bales up to the peak elevator, or used dual front-back chains surrounding the bale to lift bales straight up the side of the barn to the peak elevator.

A bale wagon pulls up next to the lifting elevator, and a farm worker places bales one at a time onto the angled track. Once bales arrive at the peak elevator, there are adjustable tipping gates along the length of the peak elevator. By pulling a cable from the floor of the hayloft, tipping gates can be opened and closed, so that bales will tip off the elevator and drop down to the floor in different areas of the loft. This permits a single elevator to transport hay to one part of a loft and straw to another part.

This complete hay elevator lifting, transport, and dropping system reduced bale storage down to a single person, who simply pulls up with a wagon, turns on the elevators and starts placing bales on it, occasionally checking to makes sure that bales are falling in the right locations in the loft.

The neat stacking of bales in the loft is often sacrificed for the speed of just letting them fall and roll down the growing pile in the loft, and changing the elevator gates to fill in open areas around the loose pile. But if desired, the loose bale pile dropped by the elevator could be rearranged into orderly rows between wagon loads.

Usage once in the barn

The process of retrieving bales from a hayloft has stayed relatively unchanged from the beginning of baling. Typically workers were sent up into the loft, to climb up onto the bale stack, pull bales off the stack, and throw or roll them down the stack to the open floor of the loft. Once the bale is down on the floor, workers climb down the stack, open a cover over a bale chute in the floor of the loft, and push the bales down the chute to the livestock area of the barn.

Most barns were equipped with several chutes along the sides and in the center of the loft floor. This permitted bales to be dropped into the area where they were to be used. Hay bales would be dropped through side chutes, to be broken up and fed to the cattle. Straw bales would be dropped down the center chute, to be distributed as bedding in the livestock standing/resting areas.

Traditionally multiple bales were dropped down to the livestock floor and the twine removed by hand. After drying and being stored under tons of pressure in the haystack, most bales are tightly compacted and need to be torn apart and fluffed up for use.

One recent method of speeding up all this manual bale handling is the bale shredder, which is a large vertical drum with rotary cutting/ripping teeth at the base of the drum. The shredder is placed under the chute and several bales dropped in. A worker then pushes the shredder along the barn aisle as it rips up a bale and spews it out in a continuous fluffy stream of material.

Field of hay bales, "curves" in field made by baler
Field of hay bales, "curves" in field made by baler

Industrial balers

Industrial balers are typically used to compact similar types of waste, such as office paper, for sale to recyclying companies in order to be used again in the production of paper, cardboard, or plastic. These balers are made of steel with a hydraulic ram to compress the material loaded. Some balers are simple and labor-intensive, but are just right for smaller volumes. Other balers are very complex and automated. These balers are for places that generate lots of waste that must be disposed of properly.

See also

Wikimedia Commons has media related to:

External links

References

  1. ^ 1972. Retrieved on 2007-02-11.
  2. ^ Today. Retrieved on 2007-02-11.

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Sci-Tech Dictionary. McGraw-Hill Dictionary of Scientific and Technical Terms. Copyright © 2003, 1994, 1989, 1984, 1978, 1976, 1974 by McGraw-Hill Companies, Inc. All rights reserved.  Read more
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