When it comes to spreading materials, whether it be fertilizer, seed, or ice melt, achieving accurate and consistent coverage is crucial. That’s where the Anderson Spreader Settings Guide steps in as your ultimate companion. This comprehensive guide is designed to help you optimize your spreading operations, saving you time, money, and effort.
The Anderson Spreader Settings Guide is the result of years of expertise and research in the field of spreading technology. Developed by a team of seasoned professionals, this guide offers invaluable insights and recommendations to ensure precise spreading, tailored to your specific needs and conditions.
One of the key features of the Anderson Spreader Settings Guide is its user-friendly format. The guide is thoughtfully organized, providing you with quick and easy access to the information you need. Whether you are a seasoned professional or a novice in the field, this guide will empower you to make informed decisions regarding spreading rates, spread width, and other critical parameters.
The Anderson Spreader Settings Guide covers a wide range of spreading materials, including granular fertilizers, grass seed, salt, sand, and more. It offers a comprehensive database of spreading rates for various materials, enabling you to achieve the desired coverage with precision. With this guide in hand, you can optimize your spreading operations, ensuring that every square inch is covered efficiently and effectively.
Anderson Spreader Settings Chart
The Andersons, a leading provider in spreading technology, offers a range of high-quality spreader models to meet various needs. Among their lineup are the Andersons Model 2000, 2000 SR, CO-1000, and the Anderson SSD Drop. In this article, we will provide you with a comprehensive list of standard spreader settings for each model, covering both generic materials and specific product sizes.
With the Andersons Model 2000, you can expect exceptional spreading performance. This versatile spreader is compatible with a wide range of materials, including granular fertilizers, grass seed, salt, and more. Our recommended spreader settings for this model ensure accurate coverage and efficient distribution, saving you time and effort.
Andersons Model 2000 Spreader Settings
Product | Settings | lbs/1000 sq. ft. | Cone Setting | Spread Width |
Kentucky Bluegrass | K | 1 | 8 | 7 |
Perennial Ryegrass | M ½ | 2 | 8 | 7 |
Poa Trivialis | M | 3 | 8 | 7 |
Tall Fescue | P | 3 | 8 | 7 |
Bermuda Grass | G | 1 | 7 | 9 |
Bent Grass | H | 0.5 | 4 | 4 |
Sports Turf (50% Bluegrass / 50% Ryegrass) | L ½ | 2 | 8 | 7 |
Andersons Model 2000 SR Spreader Settings
Product | Settings | lbs/1000 sq. ft. | Cone Setting | Spread Width |
Kentucky Bluegrass | L | 2 | 4 | 4 |
Perennial Ryegrass | O ½ | 4 | 8 | 7 |
Poa Trivialis | P | 6 | 8 | 7 |
Tall Fescue | P | 6.5 | 8 | 4 |
Bermuda Grass | H | 2 | 7 | 9 |
Bent Grass | H ½ | 1 | 4 | 4 |
Sports Turf (50% Bluegrass / 50% Ryegrass | M | 3 | 8 | 7 |
Anderson Model LCO-1000 Spreader Settings
Product | Settings | lbs/1000 sq. ft. | Spread Width |
Kentucky Bluegrass | O | 4 | 4 |
Perennial Ryegrass | R | 6 | 4 |
Poa Trivialis | X | 12 | 4 |
Tall Fescue | V | 6.5 | 7 |
Bermuda Grass | I | 3 | 9 |
Bent Grass | I | 1.7 | 4 |
Sports Turf (50% Bluegrass / 50% Ryegrass) | M½ | 4 | 4 |
Andersons SSD Drop Spreader Settings
Product | Settings | lbs/1000 sq. ft. |
Kentucky Bluegrass | 10 | 4 |
Perennial Ryegrass | 13½ | 6 |
Poa Trivialis | 18 | 12 |
Tall Fescue | 16 | 6.5 |
Bermuda Grass | 3 | 3 |
Bent Grass | 3 | 1.7 |
Sports Turf (50% Bluegrass / 50% Ryegrass) | 10 | 4 |
Here’s a quick settings chart based on product size:
Spreader Settings for Andersons Model 2000, 2000 SR, and LCO-1000 Based on Product Size
Product Size | Settings | lbs/1000 sq. ft. |
Small Granules | K½ | 4 |
Medium Granules | L½ | 4 |
Large Granules | M½ | 4 |
Cone Settings per Particle Size on Andersons Model 2000 and 2000 SR
Particle SGN | Cone Setting |
75 | 9 |
100 | 8 |
125 | 7 |
145 | 6 |
150 | 5 |
215 | 4 |
240 | 3 |
The settings provided here are based on using standard spreaders in optimal spreading conditions. However, it is important to note that the actual settings you utilize might vary slightly due to factors such as the terrain, age of the spreader, and your walking speed.
Regardless, consider these settings as a starting point and gradually adjust them within the recommended range. To test the effectiveness of the adjustments, confine the testing to no more than ¼ of the entire yard.
How to Calibrate a Spreader
There are two primary methods for calibrating a spreader: one involves mathematical calculations, while the other does not. This article will specifically address the process of calculating a spreader using the mathematical method.
Both methods are effective, and the choice between them primarily relies on personal preferences rather than the calibration results themselves.
Spreader Calibration with Mathematical Calculations
The use of mathematical calculations for spreader calibration is commonly preferred by professional top-dressers as it offers a more efficient way to achieve accurate results compared to calibrating without calculations. Here is a straightforward walkthrough of the steps you can follow to calibrate your spreader using mathematical methods:
Step #1
Prepare the spreader’s hopper by adding a measured amount of the material you wish to spread, such as seed, fertilizer, or soil treatment. It is recommended to weigh out a quantity ranging from 3 to 8 pounds. This range ensures that the spreader has an adequate amount to distribute without being overloaded.
Step #2
Create a test strip for calibration purposes, ensuring that it covers no more than ¼ of the entire yard. However, it is often beneficial to have a smaller test strip, and a longer strip measuring approximately 50 feet is generally more convenient for testing purposes.
Step #3
After walking through the 50 ft. strip and spreading the fertilizer, close the hopper and weigh the remaining amount. Subtract the weight of the leftover material from the original amount to determine the amount used. Let’s assume you used 3 pounds for the calculations.
To calculate the spread settings, use the formula “amount of fertilizer used * 1000 ÷ area of the test strip.” For rotary/broadcast spreaders, if the spreader covers a 10 ft. wide strip and we had a 50 ft. long strip, the area of the test strip would be 10 ft. multiplied by 50 ft., resulting in 500 sq. ft.
Now, you can proceed to calculate the required spreader settings. In this case, with 3 pounds used on a 500 sq. ft. test strip area, the calculation would be 3 * 1000 ÷ 500 = 6. Therefore, your spreader setting would be 4 pounds per 1000 sq. ft. If you are satisfied with this result, record the settings used on the spreader as the specified rate (lbs/1000 sq. ft.). However, if you wish to increase the application rate, simply open the spreader range further and conduct another test spread.
When using a drop spreader, start by evaluating the width opening. For example, if your fertilizer spread creates a 2 ft. wide strip, proceed with the calculation similar to that of rotary spreaders.
To determine the test strip area, multiply the width (2 ft.) by the length (50 ft.), resulting in an area of 100 sq. ft. With this information, you can continue with the normal calculations.
Assuming you used 1 pound of fertilizer on the 100 sq. ft. test strip area, the calculation would be 1 * 1000 ÷ 100 = 10. Therefore, your spreader setting would be 10 pounds per 1000 sq. ft. If the spread comes out as expected, record these settings on the spreader. Alternatively, if you desire a slightly different application rate, you can adjust the spreader settings accordingly.
Following these steps will enable you to calibrate your drop spreader accurately, achieve the desired application rate, and record the settings for future use.
Frequently Asked Questions
Table of Contents
To adjust the spreader settings, refer to the manufacturer’s instructions or documentation for your specific Anderson spreader model. This will guide you on how to modify the settings to achieve the desired application rate based on the calibration results.
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Table of Contents
The effective spreading width is calculated by multiplying the measured spreading width by a correction factor specific to your Anderson spreader model. This correction factor can usually be found in the manufacturer’s documentation.
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Table of Contents
The desired application rate can typically be found on the product packaging or obtained from reliable sources. It is important to follow the recommended application rate for the specific material you are spreading.
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Table of Contents
To measure the spreading width, mark the starting and ending points of the spreader’s path and measure the distance between them. This will give you an accurate measurement of the width covered by the spreader in a single pass.
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Table of Contents
The choice between using mathematical calculations or not depends on personal preferences and the level of precision desired. While both methods can be effective, using mathematical calculations often provides a more systematic approach and precise results.
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Conclusion
In conclusion, calibrating Anderson spreader settings is an essential step to ensure accurate and consistent material distribution. Whether using mathematical calculations or not, the calibration process helps determine the appropriate settings for achieving the desired application rate. The choice between using mathematical calculations or not depends on personal preferences and the level of precision desired. However, using mathematical calculations is often preferred by professional top-dressers due to its efficiency and reliable results.
By following the recommended steps, such as measuring the spreading width, calculating the effective spreading width, conducting test runs, and comparing actual material flow rates with desired rates, users can fine-tune their Anderson spreaders for optimal performance.
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