|
Harvest Tips & Storage
Color and Small Grain Maturity
With uneven maturity common in many fields, you may have to wait for late grain to mature, while hoping ripe grain does not shatter. Looking at head
color and kernel color will enable one to cut as soon as late grain is mature.
Here’s how it works:
- Lack of green in the flag leaf - the uppermost leaf - indicates that a wheat or barley plant has reached 95% of its ultimate yield and that the final stage of development is under way.
- Green disappears from the glumes (bracts at the bases of the spikelets) about 1 1/2 days before maturity.
- Lack of green in heads and the darkening of a pigment strand in each kernel, seen most easily when kernels are cut open crosswise, signal 100% maturity. The pigment strand begins to
appear about a half day before physiological maturity.
A whole field won’t lose its color at the same time, so check thoroughly. Also, check bottom kernels on heads because top kernels lose green first.
Preserving Malting Barley Quality at Harvest
Preventing or reducing skinned and broken kernels is the main concern during combining. Skinned kernels are those with more than
one-third of the protective husk removed from the kernel. Once skinned and broken kernels exceed 4% of the crop, barley quality and market prices are reduced. Excessive combine cylinder speeds causes the most
damage. Cylinder speeds used for threshing wheat are too fast for barley, and should be reduced.
Check the operator’s manual before making speed adjustments. Adjustments should be made in the field according to the harvest conditions. If threshing problems develop at the slow cylinder
speed, first reduce the cylinder to concave spacing. Increase cylinder speed only as a last resort and do it in small increments to avoid kernel damage. Keep returns to the cylinder to a minimum. Returning grain to
the cylinder for more threshing will cause more problems.
Harvesting Soybeans
Harvest soybeans when plants are mature and the beans have approximately 14% moisture. Harvest may be started at 17 to 18% moisture when air drying is
available. Harvest as much of the crop as possible above 12% moisture to avoid cracking seed coats and “splits.” When soybean seed is extremely dry, (8 to 10 % moisture), harvesting will cause more shattering and
seed injury. Under these conditions, combine during morning or evening hours when relative humidity is higher and adjust the combine accordingly. Adjust cylinder concave clearance according to the operator’s manual.
When soybean plants and pods are tough, cylinder speed may have to be increased.
Decrease cylinder speed as soybean seeds dry during midday to reduce breakage. Gramorie or sodium chlorate can be applied as a desiccant to aid harvesting if green weed growth delays harvest.
Do not apply a desiccant until soybean moisture is under 30% and 65% of the seed pods have reached a mature brown color. Soybeans may be stored safely for short periods during cold weather
with a moisture content as high as 14%. For safe storage during the spring or summer, soybean should not contain more than 12% moisture.
Common Harvest Mistake: Leaving Too Much Residue in Windrows
We used to say that residue management started at harvest, but nowadays it is more prudent to say that residue
management is an ongoing process. Knowing how much residue you are likely to have at the end of the harvest and making plans now to modify equipment to handle that residue will make residue management much easier.
Proper distribution of residue behind the combine is important. Wide combine headers (>15 feet) and high residue production with today’s varieties are two reasons a well-adjusted combine
is critical to no-till farming. Without special attachments or modifications, combine headers of 20 to 30 feet or more are not adequately equipped to spread today’s volumes of residue uniformly.
The most common mistake made in the harvesting operation is to allow crop residue to accumulate in windrows behind the combine. This accumulation causes the soil under the windrows to stay
wetter and cooler longer in the spring. Planting into windrows and chaff rows can result in uneven stands, because seeds take longer to germinate and grow, resulting in significant yield reductions. Other problems
associated with improper combine residue distribution include:
- Unsatisfactory weed control from herbicide interception.
- Poor performance of planters, drills and tillage equipment (particularly in a no-till system).
- Poor seed soil contact (usually from hair pinning of residue into the seed row).
- Excessive residue laying directly over the seed furrow, resulting in conditions that could inhibit germination or growth.
- Increased pest infestation (from insects and rodents).
- Increased weed seed concentration.
- Poor plant nutrient uptake (from fertilizer tie-up or interception).
To avoid these problems, make sure you always check residue distribution patterns of your equipment, whether it is new or used. The other thing you can do is to consider incorporating some
residue spreading attachments. A straw spreader uses rotating blades or rubber batts to throw or deflect whole pieces of crop residue. While the spreader typically distributes the residue more uniformly, the straw
chopper can provide more residue cover, since it chops the residue into small pieces before spreading. A straw spreader is effective in handling fine materials primarily from harvest of small grains.
The most commonly used chaff spreading attachments are hydraulically driven single or dual spinning disks that have rubber batts attached. Generally, single disk spreaders are most effective
for headers under 20 feet, while dual spreaders are more effective for wider headers.
Rainfall, high temperatures, fall tillage, or knifed in fertilizer applications can all speed the decomposition of crop residues between harvest and planting. As long as moisture is
available, decomposition can occur when temperatures are above 50°F. Even when air temperatures drop below freezing, snow can actually act as an insulator and allow decomposition to continue.
Residue from canola, beans, peas, fall-seeded cover crops, potatoes, sugar beets, and sunflower decomposes at a faster rate than residue from alfalfa, corn, grass hay, oats, sorghum, or wheat.
Specialty Crops - When To Swath and Combine
|
Crop
|
Other Information
|
|
Peas
|
When swathing, seed needs to be at physiological maturity. At this stage, majority of pods
should have turned from green to yellow. The crop matures from the bottom pods upward. Peas should be swathed in the early morning or late afternoon when the pods are tough to reduce shattering
losses. Field peas should be combined with seed moisture of 14 to 20%. At this moisture range, the seeds are firm and no longer penetrable with a thumbnail. Harvest should occur during humid
conditions to minimize seed shatter. However, pea vines must be dry or harvest will be extremely slow and difficult. Seed that is too dry will be susceptible to seedcoat breakage or peeling.
|
|
Lentil
|
Swath when lower most pods are tan colored and rattle when shaken. Thresh when seeds test
18% moisture content or lower. Overdry lentils (8-10%) are hard and difficult to process or consume. Plants may still be green when pods are ripe. Crop typically matures in patches. Some shatter loss
usually occurs. Watch out for swaths being scattered by the wind.
|
|
Mustard
|
Swath when seed moisture content is 25%. Seeds are firm when pressed between fingers.
Oriental - 75% yellow seeds. Brown - 60% reddish brown seeds. Yellow - 100% yellow seeds. Straight combine yellow mustard whenever possible. Watch for cracked seeds. Moisture content of seed should
be 13% or lower. Swaths are fluffy and subject to wind damage. Lay swaths in direction of prevailing winds. Immature green seed will not change in color in the swath. Use swath roller.
|
|
Safflower
|
Crop has finished blooming. Seeds heads are tan to brown in color. Leaves and heads are
spiny with little green evident. Crop should be straight combined if evenly matured. Mature seed is striped or white and rubs freely from the heads.
|
|
Flax
|
Flax maturity can be judged by the color of the bolls. Flax should be harvested when 90%
of the bolls turn brown. The stems may remain green after the bolls are ready to harvest. Flax with green stems is the most difficult of all grains to cut. Sharp, well adjusted cutter bars are
essential. Flax can be straight combined if maturity is uniform and green weeds not a problem. If flax is swathed and pickup combined later, a tall stubble is desired. Using swath rollers can help
settle the swaths into the stubble to reduce wind damage and aid pickup combining. The seedcoat of flax is easily damaged or broken, so proper adjustments are necessary. Yellow seeded varieties are
more susceptible to seed damage because of their thinner seedcoat.
|
|
Sunflower
|
Physiological mature when bracts are yellow/brown and little green remains on back of
heads. Common threshing mistake: waiting to harvest and seeds become too dry and shell out. Better: combine at 14-15% moisture and dry down to under 10% moisture.
|
|
Duane Berglund, NDSU extension agronomist
|
Grain Temperature Key to Grain Storability
Maximum recommended moisture content for wheat is 14% (wet basis) for
up to 9 months storage, and 13% for more than 9 months storage. Barley moisture should be 13.5% and 12.5%, respectively, for the same storage periods.
Dry grain should be cooled to less than 60° as soon as possible after harvest, and to 20 or 30° for winter storage.
Stored grain should be cooled by aeration whenever the grain temperature exceeds the average outdoor temperature by 10 to 15 degrees. Expected
allowable storage time approximately doubles with each 10 degree reduction in temperature. Grain should be cooled to about 25 degrees as outdoor temperatures get colder. Grain that has been dried with high
temperature dryers will have a moisture variation across the kernel as it comes from the dryer. This will cause an error in the moisture measurement
. The grain should be checked at least 12 hours after drying to determine if the grain moisture content has changed.
Check the condition of stored grain about every two weeks while grain is cooling, then about monthly after grain has cooled. A check should include
measurements of moisture content and temperature at several locations. Moisture measurement accuracy is dependant on the grain temperature, so
it is best to collect a grain sample, let it warm to room temperature in a plastic bag or other sealed container, then check the moisture content. Also
, be sure to cover fans and ducts after the grain has been cooled for winter storage to prevent snow from blowing into the bins.
Wheat Drying Time (69oF and 60% relative humidity. Average ND condition for August)
|
Moisture
|
Airflow
|
Fan Time
|
|
Content
|
(cfm/bu)
|
Hours
|
Days
|
|
18%
|
1.25
1.00
|
480
600
|
20
25
|
|
17%
|
1.00
0.75
|
552
744
|
23
31
|
|
16%
|
1.00
0.75
0.50
|
504
672
1,008
|
21
28
42
|
|
15%
|
1.00
0.75
0.50
|
480
648
960
|
20
27
40
|
|
14%
|
1.00
0.75
0.50
|
408
544
816
|
17
23
34
|
Eastern ND Environment
|
|
|
|
Equilibrium Moisture Content (EMC)
|
|
Month
|
Temp (oF)
|
Relative Humidity
|
Wheat
|
Corn
|
Oil Sunflower
|
Soybeans
|
|
August
|
67
|
66%
|
14.1
|
|
|
|
|
September
|
56
|
68%
|
15.0
|
|
|
|
|
Oct/Apr
|
44
|
69%
|
15.9
|
16.0
|
9.0
|
13.4
|
|
Nov/Mar
|
25
|
78%
|
19.0
|
19.5
|
11.0
|
17.0
|
Drying conditions vary across the Northern Plains and vary by month. Shown above are the equilibrium moisture contents for some crops based on the average climatic conditions in eastern North Dakota. This can be
used to estimate the potential for drying in the field as well as in the bin. The moisture content would be expected to be lower than the table value during
a warm, dry afternoon, because the table value is the 24 hour monthly average. The expected final moisture content when natural air drying, will
likely be slightly lower than the table value because the air is heated 3-5° F as it goes through the fan. (Source: Ken Hellevang, NDSU Extension Ag Engineer)
How to Estimate Grain Harvest Losses
Studies have shown that losses off the combine can run as high as 20%,
even with a properly adjusted machine when it is overloaded. A reasonable loss is considered to be 3% of the total crop or less. Total harvest losses are seldom if ever zero.
Usually over 60% of the grain left in the field is due to shattering of the crop and grain lost in getting it cut and into the combine header. Once the crop is
in the combine, loss is very low with properly adjusted and operated equipment.
To keep harvest loss low, determine how much grain is being left in the field. A simple, accurate method to estimate losses requires the use of a
one-foot square frame. Pick several typical areas in the field after the combine has passed and follow these steps.
- Count the kernels left directly behind the rear of the combine. Count several separate square foot areas (A- Figure 1).
- Count the kernels already in the field due to shatter and cutter bar loss (B- Figure 1).
- Subtract (B) from (A).
- Divide the results of Step 3 by the ratio of: Width of windrower/header width (ft) Width of combine (ft).
- Divide the result of Step 4 by the number of kernels for the particular crop from the Table 1 (below) for one bushel per acre
loss. This is the approximate machinery loss in bushels per acre.
- To find total loss, add the count in (B) to the result in Step 4. This gives the total seed count from shatter, cutter bar and machine loss.
- Divide the total seed count of Step 6 by the number of kernels for the particular crop for one bushel per acre loss (Table 1). This will
give the approximate total loss in bushels per acre.
- For a percentage loss, divide the loss in Step 7 (loss in bushels per acre) by the total yield (harvest yield plus loss) in bushels per acre for the field.
Table 1. Number of kernels per square foot to equal one bushel per acre loss
|
Crop
|
Number of Kernels / ft2
|
|
HRS Wheat
|
20
|
|
Durum
|
16
|
|
Barley
|
14
|
|
Oats
|
10
|
Source: University of Minnesota Extension Service
Counting Kernels to Measure Harvest Loss
Kernels or seeds per pound, bushel, cwt, and number per square foot to equal one unit loss per acre at harvest
|
Crop
|
No. per pound* to equal 1 bushel unit loss/A
|
No. per square foot
|
|
Spring Wheat
|
14,300
|
20
|
|
Durum Wheat
|
11,500
|
16
|
|
Barley
|
13,500
|
15
|
|
Oats
|
15,500
|
11
|
|
Flax
|
88,000
|
113
|
|
Rye
|
18,000
|
42
|
|
Soybeans (Small)
|
3,300
|
4
|
|
Soybeans (large)
|
2,400
|
4
|
|
Corn (Medium grade)
|
1,500
|
2
|
|
Sunflower (oil)
|
9,000
|
5
|
|
Sunflower (confc.)
|
5,000
|
2.5
|
|
Navy Beans
|
2,500
|
4
|
|
Pinto Beans
|
1,250
|
2
|
|
Sorghum
|
15,000
|
18
|
|
Sudangrass
|
44,000
|
40
|
|
Proso Millet
|
80,000
|
84
|
|
Foxtail Millet
|
220,000
|
242
|
|
Buckwheat
|
15,000
|
16
|
* These are average numbers from past seasons, and individual varieties or hybrids will vary among themselves as well as be influenced by environmental factors. Source: NDSU
|
