Because of the harsh winter and drought
conditions we are low on hay inventories.
You never know how you will benefit from storing hay until you test it.
There is no doubt if you store hay out of the weather you will dramatically decrease
yield losses. Quality; however will
change, but not as much as you think. The following information was developed
by Dennis R. Buckmaster, Assistant Professor of Agriculture Engineering.
Mechanically-induced
losses during forage harvest are visible and are commonly recognized as a
source quantity and quality loss. Although invisible, similar losses occur
during hay storage because of microbial respiration on the hay. This
respiration results in dry matter loss as well as quality reduction.
The
dry matter lost during storage consists of the most nutritious parts of the hay
(nonstructural carbohydrates). As a result, hay quality is affected in a manner
which decreases its potential intake and digestibility. Heat generation, also
associated with the respiration, reduces protein availability.
Moisture
content also decreases during storage. Given enough time in storage (usually
two months or more), most hay will reach approximately 12 percent moisture if
baled at less than 25 percent moisture. If not treated with an effective
preservative, hay baled above 25 percent moisture poses the threat of severe
heat production and a barn fire.
Forages
are made up of dry matter (DM) and water. While the water has no nutritional
value, it can have economic value because hay is often sold by weight on an “as
is” basis rather than on a dry matter basis. Hay buyers and sellers should have
hay sampled for dry matter content because this, in combination with the weight
and quality, determines the amount of nutrients being transferred.
Chemical
preservatives change the storage process. Although the changes in treated hay
would be similar to those discussed here, this fact sheet applies specifically
to untreated alfalfa hay.
Dry Matter Loss in Baled Hay
Dry matter loss is a direct result of
microbial activity. During this microbial activity the soluble carbohydrates in
the hay are consumed. The amount of dry matter loss is directly related to heat
generation, which in turn is related to moisture content. For hay baled near 12 percent moisture, very
little loss occurs. As baling moisture rises, the amount of storage dry matter
loss increases. This dry matter loss results in less feed and lower quality
feed. Trade-offs occur between storage losses and harvest losses; but, in
general, hay baled at 15 to 18 percent moisture will maximize the overall
nutrient yield.
Consider
one ton of alfalfa hay baled at 18 percent moisture (82 percent DM) is placed
into storage. The amount of dry matter going into storage is 1,640 lbs. (2,000
x 82 percent DM). With a dry matter loss of 2.5 percent, only 1,600 will be
available after storage. At 12 percent moisture (88 percent DM), the total
weight as removed from storage would be 1,820 lbs. while the initial weight was
2,000 lbs. From a hay sellers perspective (in this example), the price needs to
be at least 10 percent higher after storage than at baling because of the
weight change.
Quality Effects
The dry matter consumed during
hay storage is primarily nonstructural carbohydrate which is readily used by
ruminant animals. The fibrous plant components are retained and, as other dry
matter is lost, their concentration increases. A slight amount of crude protein
is lost during storage, but protein is lost at a slower rate than carbohydrates;
thus, crude protein concentration increases slightly during storage.
The
NDF concentration will also increase, which in return will decrease quality
because intake of the alfalfa by ruminant animals will now be lower. Acid
detergent fiber (ADF) also increases; this indicates that digestibility of the
hay after storage will be slight lower than that of the freshly baled hay.
Although the increase in CP content appears to be a good consequence, the total
amount of protein removed from storage is less than the amount put into
storage.
Another quality change occurring during
storage of alfalfa hay, or any hay for that matter, concerns the acid detergent
insoluble protein (ADIP) (this is sometimes called ADIN or ADF-N if expressed
on a nitrogen rather than a protein basis). This protein is unavailable to
ruminant animals. Formation of ADIP is directly related to heat development.
Hay
producers and feeders need to be aware of changes occurring to hay during
storage. In a feeding program, it would be best to take forage samples near the
time of feeding rather than at the time of baling so as to more accurately
reflect what the animal would be getting. Similarly, purchased hay should be
sampled at the time of the purchase for a better indication of the quantity of
dry matter being purchased as well as the quality of the purchase.
For
more information please contact Texas A&M AgriLife Extension, Wise County
at 940-627-3341.
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