How real time protein mapping drives fertiliser decisions

Profit driver: Protein mapping drives fertiliser decisions

Cropping
PROFIT DRIVER: Phil Clancy from Next Instruments says farming is about converting water into grain and this can be helped by combining yield and protein mapping.

PROFIT DRIVER: Phil Clancy from Next Instruments says farming is about converting water into grain and this can be helped by combining yield and protein mapping.

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Phil Clancy from Next Instruments says farming is about converting water into grain and this can be helped by combining yield and protein mapping.

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REAL time protein mapping technology may provide the missing link for growers looking to better identify the causes of lost revenue in their paddocks and capture protein premiums with grain sales more frequently.

Developed by Australian company Next Instruments, The CropScan 3000H On Combine Analyser was one of the key presentations to growers and agronomists at the GRDC Updates at Pallamallawa, in northern NSW recently.

Developer Phillip Clancy said protein mapping will complete the story on soil and plant performance that is only partially provided by yield mapping.

“Yield mapping has provided significant improvements in productivity and profitability, but by combining yield mapping with protein maps, growers can more completely understand the variations that occur across the paddock,” he said.

“They can then use variable rate fertiliser applications to achieve the optimum yield across fields. Real-time protein data can then help to determine where in the field nitrogen should be applied and at what rate.

"High yield and high protein indicates that the plant has reached its full potential - the ‘sweet spot’.”

One grower in South Australia has combined yield mapping with a protein map to show that the problem with yield was there was insufficient nitrogen available in the emergence and tillering stages, but there was enough nitrogen for the growth stages of sections of the crop.

“In other sections of the same paddock, the yield was high however the protein map shows that the average protein level was lower than expected,” Mr Clancy said.

“As a result of the analysis, it was found the grower was leaving approximately $10,000 value in the paddock because he did not achieve the optimum yield and protein grades.”

Real time protein mapping works whereby near infrared (NIR) light passes through a sample of grains as they are being harvested, and is transmitted to a NIR spectrometer located in the cabin. Data is then sent to a cabin mounted touch screen personal computer where calibration models are applied for protein, moisture and oil.

As the harvester bin fills with grain, the bin protein averages are displayed in real time so that the operator can make decisions about segregating grain or selectively stripping different parts of the paddock. 

Mr Clancy said the second major use of real time protein mapping is as a tactic to maximise protein grade payments and is already generating significant profit gains for many grain growers.

“One grower using the technology for in-paddock blending noticed a variation of up to 5pc in protein levels across one paddock,” Mr Clancy said.

“He was able to monitor protein levels as the bin filled and switch to a lower or higher protein section of the field until the bin average reached 13.5pc. He reported that every load was accepted as APH1 grade which at the time attracted a $30/tonne premium.

“This practice generated an estimated additional $40,000 in grain payments across the farm.

“In a slightly different application, another farmer in NSW is using real time protein data to segregate grain by protein level before it is stored on farm. The protein, moisture and weight of every truck load that is stored into each silo is recorded by the system and is made available to their grain marketing consultant.

“Grain is then marketed from each silo with confidence that the protein will meet the buyer’s requirements. This system has led to higher prices received per tonne and no costly rejected loads for the grower.”

In summary Mr Clancy said the technology had two major application streams on-farm:

Tactical    

- In paddock blending of grain to maximise protein grade payments.

- In paddock segregation and storage to maximize protein grade payments.

- On farm segregation and storage into on farm silos.

Strategic   

- Protein/Nitrogen/Yield Optimization to find the ‘sweet spot’.

- Reduction in nitrogen fertiliser or better use of nitrogen fertiliser.

“Farming is about converting water into grain. When there is sufficient water available, then the grower’s task is to optimise the yield and to get the best price for the grain,” Mr Clancy said.

“By combining yield and protein maps, growers can more completely understand the variations that occur across the paddock.”

He said growers are then able to use variable rate fertiliser applications to achieve the optimum yield across paddocks with real-time protein data able to help determine where in the paddock nitrogen should be applied and at what rate.

CLICK HERE for more information on yield mapping.

The story How real time protein mapping drives fertiliser decisions first appeared on Queensland Country Life.

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