Corn: Harvesting and Storage

Excerpt from Agronomy Guide for Field Crops (Chapter 3)

Order OMAFRA Publication 811: Agronomy Guide for Field Crops

Table of Contents

1. Introduction
2. Harvesting and Storing Corn Silage
3. Corn Storage
   • Drying and Storing Corn
4. Drying Corn With Heated and Unheated Air
5. Drying Temperatures
   • Maximum Recommended Air Temperatures for Drying Corn of Various End Uses - Table 3-23
6. Kernel Quality
7. Natural-Air Drying
   • Minimum Requirements for Natural-Air Drying
   • When to Run the Fan
8. Equilibrium Moisture Content
   • Equilibrium Moisture Content (% Wet Basis) for Corn Exposed to Air at Various Temperatures and Humidity - Table 3-24
9. Updates on Corn: Harvesting and Storage
10. Related links...

Introduction

Physiological maturity (black layering) occurs when the grain moisture content is approximately 31%-33% moisture. After this stage there is no dry matter added to the corn kernel. Harvesting grain corn at moisture contents above 28% often results in significant damage to the grain and makes it more difficult to market commercially. High quality food grade markets may require harvest moistures to be as low as 20%-22%.

Growers must weigh the benefits of delaying harvests to lower drying cost and improve sample quality versus the increased risks that come from higher levels of stalk lodging, ear drop and wet weather. The need to adjust harvesting dates forward to prevent harvest losses is determined by scouting fields and checking for stalk quality. When stalk quality is poor, the next significant wind or rainstorm may increase harvest losses dramatically. Efficient header performance is also important when harvesting corn of low stalk strength. Keep header speed in-step with ground speed to improve stalk flow down through the stripper plates and snapping rolls. These may also need to be adjusted to be brought closer together.

Corn damage to grain quality by the combine can result from any of the following:

1. cylinder speed too high
2. concave clearance too narrow
3. too many concave filler bars
4. concave and cylinder not parallel

Ontario experience with harvesting corn that has been frozen prior to maturity generally indicates that running the cylinder speed as slow as possible is the key to maintaining quality.

To assess harvest losses from your combine, consider the following guidelines: 22 kernels per square metre (2 kernels per square foot) represent approximately 0.06 t/ha (1 bu/ac) in losses and one average-sized ear in 1/100 ac represents 0.06 t/ha in lost yield. If combine losses exceed 0.16 t/ha (2.5 bu/acre), adjustments are warranted.

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Harvesting and Storing Corn Silage

For a full discussion, see the section Haylage and Corn Silage.

Corn Storage

Drying and Storing Corn

The three basic general types of grain dryers used on the farm are:

• in-bin
• batch
• continuous flow

No single drying system is superior to all others in every respect. System selection is dependent on desired features including drying capacity, grain quality, fuel/drying efficiency (BTUs per kilogram of water removed), convenience, manpower required to run the dryer, ability to dry a variety of crops, maintenance required and capital cost.

All dryers move air past the grain to evaporate moisture within the kernel and carry the water vapour away. Heat is added to this drying air to reduce its relative humidity, thereby increasing its ability to pick up moisture. Wet grain can be dried at higher temperatures since it will be cooled as the moisture evaporates from the kernels. As the grain dries, it will approach the temperature of the drying air. The longer that grain kernels are in contact with this heated air, the drier and hotter the kernels will get.

Drying Corn With Heated and Unheated Air

Corn dries as the moisture from the inside of the kernels is evaporated from the kernel surface. Most of the moisture inside the kernel exits through the tip end of the kernels. The first few points of moisture can be easily removed using relatively little energy. Further moisture must be removed from deep within the corn kernels. As the outside layers of the kernel dry, the moisture must migrate out from the moist centre. This moisture does not move to the surface as quickly as it is being evaporated from the surface of the kernel by the drying air. This results in higher energy requirements to remove the last few percentage points of moisture.

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Drying Temperatures

A range of drying temperatures can be used to dry corn but should not exceed the maximum recommended air temperatures displayed in Table 3-23. Maximum Recommended Air Temperatures for Drying Corn of Various End Uses. The maximum recommended drying temperature depends on several factors including final end use of the grain, initial moisture content of the grain, type of grain and type of dryer.

Viability is destroyed when the actual grain temperature exceeds approximately 50°C (122°F). Reduction in nutritional value occurs when grain temperature reaches 90°C to 100°C (194°F to 212°F).

Kernel Quality

Taking corn hot out of the dryer, allowing it to steep for a time and then aerating the corn with a minimum of 6.5 L/sec/m3 (.5 CFM/bu) airflow will reduce stress cracking.

Stress cracking and physical kernel damage are influenced by the speed of moisture removal and also by maximum kernel temperature, coupled with the rate of cooling after drying.

In addition to maintaining grain quality, using this system of dry-aeration or cool-aeration can increase the throughput of the drying system.

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Natural-Air Drying

Natural-air drying of corn is possible in most parts of southern Ontario. This method of drying corn is well suited for livestock operations to produce high-quality corn that is free of stress cracks. Good management of a natural-air drying system is critical to success.

Minimum Requirements for Natural-Air Drying

• Full aeration floor in the bin
• Level grain surface across the whole bin
• Minimum airflow of 26 L/sec/m3 (2 CFM/bu), preferably more
• Corn 25% moisture content or less
• Clean corn with no cob pieces or fines
• Accurate moisture reading of the corn in the bin
• Accurate outside air temperature and relative humidity measurement
• An understanding of corn equilibrium moisture content
• Coring the bin (auger out some grain) after filling. The best way is to remove a couple of loads from the bin. This establishes the flow funnel and removes the highest concentration of fines from the centre of the bin. These loads should be cleaned before placing them back into the bin, otherwise the unclean loads will make the resistance to airflow less than if the bin had not been cored.
• An on/off switch for the fan

When to Run the Fan

Fan operation in a natural-air corn-drying bin is slightly different than for other air-dried crops. Once there is sufficient corn in the bin to hold the perforated floor down, the fan can be turned on. The fan should remain on continuously for the first 3 weeks after the bin has been filled or the first drying front has come through the top of the bin.

The first drying front will be evident when there is a noticeable drop in the moisture content of the corn at the top of the bin. Before this drying front passes through, the corn at the top of the bin will remain at harvest moisture levels and may even increase slightly compared with the corn drying further down. If the fan is shut off for an extended period of time at the start of the drying process, there is a risk that the drying front moving through the corn may stall and will not move upwards once the fan is turned on again. This will result in spoilage occurring above the drying front.

Rain or shine, the fan should not be turned off until the first drying front has passed through the whole bin.

Once the first drying front passes through the top of the bin, begin to manage the fan operation, using the equilibrium moisture chart for corn. (See the section Equilibrium Moisture Content). The fan should be run any time the outside conditions will still allow drying to occur, even with the wettest corn. At times, this procedure may add some moisture to the corn at the bottom of the bin and will actually dehumidify the air so it can do more drying up further in the pile.

The corn may not reach the desired moisture content before freezing weather arrives. Trying to accomplish natural-air drying in below-freezing temperatures is very slow and inefficient. The last few points of moisture may have to be taken out in early spring. Some producers never finish drying the corn any further after winter, since it processes and stores well as feed at the higher moisture levels.

Humidistats are available that will activate the fan at preset humidity levels. The operator can adjust the relative humidity level at which the fan is activated. Bins with stirrators will have fairly uniform moisture levels throughout the whole bin as a result of the mixing that has occurred.

Corn at moisture levels greater than 25% can also be dried in a natural-air bin. This works by only partially filling your natural-air bin, resulting in an airflow of 52-78 L/sec/m³ (4-6 CFM/bu). Producers who need corn for feed in late September can harvest headlands and put this in the bin. The warm temperatures in late September, combined with higher CFM/bu airflow enable this corn to be dried in a couple of weeks.

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Equilibrium Moisture Content

Researchers have developed equilibrium moisture content tables that allow you to predict the final moisture content of corn when exposed to air at a certain temperature and relative humidity (see Table 3-24. Equilibrium Moisture Content (% Wet Basis) for Corn Exposed to Air at Various Temperatures and Humidity). For example, to determine the equilibrium moisture content of corn exposed to outside air at 10°C (50°F) and 70% relative humidity, find the point at which the 10°C (50°F) line and the 70% relative humidity line intersect. This point will be the equilibrium moisture content for corn at the outside air conditions stated.

Updates on Corn: Harvesting and Storage

No updates available at this time.

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Related links...

• Corn

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