The dairy industry is a constantly evolving business. Management practices change with new technology and regulations that move the industry toward increased economic and
environmental sustainability. Management strategies can also loosely be divided into intensive and extensive systems. Extensive systems operate based on a low input and low output philosophy, where intensive systems adopt a high input high output philosophy. These philosophies as well as available technologies, local regulations, and environmental conditions manifest in different management of nutrition, housing, health, reproduction and waste. Most modern dairy farms divide the animals into different management units depending on their age, nutritional needs, reproductive status, and milk production status.
Housing systems Dairy cattle housing systems vary greatly throughout the world depending on the climate, dairy size, and feeding strategies. Housing must provide access to feed, water and protection from relevant environmental conditions. One issue for housing cattle is temperature extremes. Heat stress can decrease fertility and milk production in cattle. Providing shade is a very common method for reducing heat stress. Barns may also incorporate fans or tunnel ventilation into the architecture of the barn structure. Overly cold conditions, while rarely deadly for cattle, cause increases in maintenance energy requirements and thus increased feed intake and decreased milk production. During the winter months, where temperatures are low enough, dairy cattle are often kept inside barns which are warmed by their collective body heat. Feed provision is also an important feature of dairy housing. Pasture based dairies are a more extensive option where cows are turned out to graze on pasture when the weather permits. Often the diet must be supplemented with when poor pasture conditions persist. Free stall barns and open lots are intensive housing options where feed is brought to the cattle at all times of year. Free stall barns are designed to allow the cows freedom to choose when they feed, rest, drink, or stand. They can be either fully enclosed or open air barns again depending on the climate. The resting areas, called free stalls, are divided beds lined with anything from mattresses to sand. In the lanes between rows of stalls, the floor is often make of grooved concrete. Most barns open onto uncovered corrals, which the cattle are free to enjoy as the weather allows. Open lots are dirt lots with constructed shade structures and a concrete pad where feed is delivered.
Milking systems Life on a dairy farm revolves around the milking parlor. Each lactating cow will visit the parlor at least twice a day to be milked. A remarkable amount of engineering has gone into designing milking parlors and milking machines. Efficiency is crucial; every second saved while milking a single cow adds up to hours over the whole herd.
Milking machines Milking is now performed almost exclusively by machine, though human technicians are still essential on most facilities. The most common milking machine is called a cluster milker. This milker consists of four metal cupsone per teateach lined with rubber or silicone. The cluster is attached to both a milk collection system and a pulsating vacuum system. When the vacuum is on, it pulls air from between the outer metal cup and the liner, drawing milk out of the teat. When the vacuum turns off, it gives the teat an opportunity to refill with milk. In most milking systems, a milking technician must attach the cluster to each cow, but the machine senses when the cow has been fully milked and drops off independently.
Milking routine Every time a cow enters the parlor several things need to happen to ensure milk quality and cow health. First, the cow's
udder must be cleaned and disinfected to prevent both milk contamination and udder infections. Then the milking technician must check each teat for signs of infection by observing the first stream of milk. During this processes, called stripping the teat, the milking technician is looking for any discoloration or chunkiness that would indicate
mastitis, an infection in the cow's
mammary gland. Milk from a cow with mastitis cannot enter the human milk supply, thus farmers must be careful that infected milk does not mix with the milk from healthy cows and that the cow gets the necessary treatment. If the cow passes the mastitis inspection, the milking technician will attach the milking cluster. The cluster will run until the cow is fully milked and then drop off. The milk travels immediately through a cooling system and then into a large cooled storage tank, where it will stay until picked up by a refrigerated milk truck. Before the cow is released from the milking stalls her teats are disinfected one last time to prevent infection. Pasture based dairy producers invest much time and effort into maintaining their pastures and thus feed for their cattle. Pasture management techniques such as
rotational grazing are common for dairy production. Many large dairies that deliver food to their cattle have a dedicated nutritionist who is responsible for formulating diets with animal health, milk production, and cost efficiency in mind. For maximum productivity diets must be formulated differently depending on the growth rate, milk production, and reproductive status of each animal. Cattle are classified as
ruminants (suborder belonging to the order ) as they are able to acquire nutrients from even low quality plant-based food, thanks mainly to their symbiotic relationship with the microbes that
ferment it in a chamber of their stomachs called the
rumen. The rumen is a literal micro-ecosystem within each dairy cow. For optimal digestion, the environment of the rumen must be ideal for the microbes. In this way, the job of a ruminant nutritionist is to feed the microbes not the cow. The nutritional requirements of cattle are usually divided into maintenance requirements, which depend on the cow's weight; and milk production requirements, which in turn depend on the volume of milk the cow is producing. The nutritional contents of each available feed are used to formulate a diet that meets all nutritional needs in the most cost effective way. Notably, cattle must be fed a diet high in fiber to maintain a proper environment for the rumen microbes. Farmers typically grow their own forage for their cattle. Crops grown may include
corn,
alfalfa,
timothy,
wheat,
oats,
sorghum and
clover. These plants are often processed after harvest to preserve or improve nutrient value and prevent spoiling. Corn, alfalfa, wheat, oats, and sorghum crops are often anaerobically fermented to create
silage. Many crops such as alfalfa, timothy, oats, and clover are allowed to dry in the field after cutting before being baled into
hay. To increase the energy density of their diet, cattle are commonly fed cereal grains. In many areas of the world, dairy rations also commonly include byproducts from other agricultural sectors. For example, in California cattle are commonly fed almond hulls and cotton seed. Feeding of byproducts can reduce the environmental impact of other agricultural sectors by keeping these materials out of landfills.
Reproductive management Female calves born on a dairy farm will typically be raised as replacement stock to take the place of older cows that are no longer sufficiently productive. The life of a dairy cow is a cycle of pregnancy and lactation starting at puberty. The timing of these events is very important to the production capacity of the dairy. A cow will not produce milk until she has given birth to a calf. Consequently, timing of the first breeding as well as all the subsequent breeding is important for maintaining milk production levels. Holstein heifers reach puberty at an average body weight between 550 and 650 lbs.
Estrous cycle Puberty coincides with the beginning of
estrous cycles. Estrous cycles are the recurring hormonal and physiological changes that occur within the bodies of most mammalian females that lead to ovulation and the development of a suitable environment for embryonic and fetal growth. The cow is considered
polyestrous, which means that she will continue to undergo regular estrous cycles until death unless the cycle is interrupted by a pregnancy. This method of insemination quickly gained popularity among dairy producers for several reasons. Dairy bulls are notoriously dangerous to keep on the average dairy facility. AI also makes it possible to speed the genetic improvement of the dairy herd because every dairy farmer has access to sperm from genetically superior sires. Additionally, AI has been shown to reduce spread of
venereal diseases within herd that would ultimately lead to fertility problems. Many producers also find it to be more economical than keeping a bull. On the other hand, AI does require more intensive reproductive management of the herd as well as more time and expertise. Detection of
estrus, becomes reliant on observation in the absence of bulls. It takes considerable expertise to properly inseminate a cow and high quality sperm is valuable. Ultimately, because dairy production was already a management intensive industry the disadvantages are dwarfed by the advantages of the AI for many dairy producers. This colostrum is not usually commercially sold, but is extremely important for early calf nutrition. Perhaps most importantly, it conveys passive immunity to the calf before its immune system is fully developed. ==Concerns==