By Lee Rinehart, NCAT Agriculture Specialist
Published August, 2017
This manual provides all the resources you need to write your own grazing plan, monitor its efficacy, and adjust your management throughout the grazing season. Periodically reviewing your plan and records will help you assess how well you are working toward your goals, and will suggest ways to improve the next season. The manual starts with a discussion of grazing principles and how to conduct a resource assessment, followed by a step-by-step process for writing a grazing plan. A template and instructions are provided. This manual covers the importance of developing a simple pasture-monitoring system and provides further resources to assist producers with planning, charting, and recording grazing throughout the season. Additional resources help you understand grazing concepts, as well as obtain access to some good, online tools for recordkeeping and monitoring.
Photo: Lee Rinehart, NCAT
Planning is the first step in any successful farm enterprise. The benefits that accrue to graziers from having a grazing plan include greater forecasting ability for grazing decision-making, extension of the grazing season, more consistent supply of forage, greater dry-matter intake from pasture, and increased pasture sustainability.
Implementing an effective grazing plan is about applying observation to management, observing some more, adjusting as needed, and recording your plan in a simple, easy-to-access format. There are five steps in developing a grazing plan. They are (1) set goals, (2) inventory resources, (3) match available forage to animal needs, (4) develop a grazing schedule, and (5) monitor the effectiveness of the grazing plan.
This manual was developed to be a logical tool to help you write your plan. Each section builds on the previous and is designed to be used with the grazing plan template. Using this manual, you can capture crucial information to help you make adjustments from season to season, and year to year.
A pasture is a dynamic ecosystem encompassing numerous complex interactions among organisms and elements. Managing livestock grazing involves an understanding of these interactions and relationships. The sun drives the system, providing energy for plants to generate sugars from oxygen, carbon, and hydrogen. These sugars feed the plants and the microorganisms associated with them in the soil profile. Soil microorganisms move nutrients around, feeding themselves and contributing to the plants' nutrient needs through mineralization, while producing glomalin that holds soil particles together in aggregates. These aggregates, or large, porous soil particles, provide habitat for microorganisms, pore space for water and air, and storage for nutrients. Finally, animals, bacteria, and other organisms complete the cycling of nutrients through grazing, feeding, and contributing organic matter back to the soil. A soil that is well aggregated, rich in organic matter and biological life, and grazed appropriately is a resilient ecosystem, and is resistant to drought, erosion, and nutrient leaching. Think of it as one big merry-go-round of cycling nutrients and water.
Illustration: USDA Soil Biology Primer
Perennial pastures, because of permanent cover and the lack of soil disturbance, are higher in carbon and organic matter than tilled crop fields. This provides a stable habitat for microorganisms, and the nutrient cycles can sustain themselves. However, adding livestock to the mix has a multiplier effect on soil health, even in systems that are cover-cropped with a cash crop as part of the rotation.
The impact of grazing is known to increase soil carbon and nitrogen stocks. As an animal grazes, it sends a signal to the plant to pump out sugars through its roots and into the surrounding soil, or rhizosphere. These root exudates (sugars developed by the plant through photosynthesis) are food sources for the microorganisms in the soil. The action of grazing jump-starts the soil food web and increases nutrient cycling, making nitrogen, phosphorus, and carbon available to the growing plants.
As a grazier, you can take advantage of the benefits of grazing and plant diversity to build healthy soils and provide fertility to the system, while using less fertilizer and pesticide. Diverse perennial pastures and cover crops in annual rotations contribute organic matter to the soil and feed microorganisms that ensure nutrient cycling. Soils that are well aggregated with various-size soil particles, and that have many different plants growing for most of the year, are resilient and restorative.
And when you add a well-managed grazing plan to the system, you get the benefit of animal impact that contributes organic matter and biology to the soil system. Increases in soil aggregation, organic matter, and diversity buffer soil temperatures, preserve water, and minimize soil compaction. In short, the functionality of your soil improves.
A diverse pasture mix of rye, peas, and brassicas builds healthy soil and provides high-quality forage. Photo: Lee Rinehart, NCAT
A grazing system is just an organized, planned way of using the pasture resource to ensure that the animals receive the right amount of high quality forage while maintaining the productivity and vigor of the pasture and soil. A grazing system should result in the highest forage production and use per acre, have variable stocking rates based on the pasture plants' need for recovery, provide an even distribution of manure, control weeds through grazing or trampling, and provide more grazing options while reducing the need for mechanically harvested forages for most of the year.
The best way to ensure this is to develop a grazing plan and schedule that rotates animals from paddock to paddock and allows adequate time for plant recovery. Consider the following principles in planning a grazing system:
Recovery period is all about plant regrowth and is fundamental to developing a grazing schedule. It is important to plan for increasing recovery time when grass growth slows down. Grazing period is the length of time animals are exposed to a paddock and is important in maintaining post-grazing residual. Be sure to allow adequate stubble height and enough leaf area for plant regrowth, or you'll slow the process down. Following are some things you can do to help manage recovery and grazing periods:
High animal density is a useful management tool that allows plants to be grazed more evenly. It encourages a more even distribution of urine and manure and returns a substantial amount of carbon (trampled organic matter) to the soil to feed soil microorganisms. Livestock that are more concentrated on a paddock tend to consume a more diverse diet, as grazing selectivity for the most palatable plants decreases. In addition, high animal impact forces plants to grow closer together, forming tighter plant communities and decreasing bare spots. High animal density for short periods of time (several hours to a day per grazing period) more efficiently uses grazing resources, but requires more frequent animal moves from paddock to paddock. Animal densities of greater than 100,000 pounds per acre are recommended. There is great potential to increase the numbers of paddocks and the number of animals on a farm through high density, multi-paddock rotational grazing.
The next principle to consider is paddock size and number. How big should they be, and how many should you have to ensure animals get enough dry matter intake and the forage base stays healthy? This is likely the most important, most fundamental question a grazer can ask. Everything else stems from this. As you work through this manual, you'll find that calculating paddock size and number is what will balance the amount of forage you have with the number of animals you are grazing.
Animals must remain in a paddock long enough for them to get their fill, but not so long that they begin to graze plant regrowth. Plants may have grazable regrowth after two to three days, and the shorter the period in the paddock, the better the plant and animal production per acre. Short grazing durations also foster increased animal intake and provide higher quality forages than if the animals are in the paddock for longer periods of time. In fact, as animals remain in a paddock (for more than a few days) their intake of protein decreases, as does availability of high quality digestible dry matter (energy). This is one reason dairy producers who graze high-producing cows will move animals to a new paddock daily, or even a few times a day.
Paddocks should be sized small enough for uniform grazing of forage while providing enough dry-matter intake for the livestock during the grazing period. This manual will help you determine paddock size as a way of balancing your livestock's feed requirements with the amount of forage growing in the paddocks. In the next section, we will discuss resource assessment, including estimating forage dry-matter availability. With this, and an estimate of your livestock's forage needs, your grazing plan will begin to take shape.
Your grazing plan may need to be adjusted as the season progresses, due to precipitation (either a lack or an excess) and forage growth. This can be done by either speeding up or slowing down the rotation, or adjusting the size of the paddocks. For example, if you have to keep animals on a paddock a long time, it most likely indicates surplus forage (i.e., early season), and you may have to either adjust your paddock sizes, harvest excess forage with other livestock, or take it off as hay. On the other hand, if your livestock are eating faster than pasture can grow, you may need to sell some stock or find another pasture to use.
Putting time and energy into planning paddock sizes and moves leads to efficiencies of pasture use. Go even further by thinking how you can extend the grazing season and take advantage of reduced feed costs. Lengthening your grazing season can be accomplished by grazing winter crops or stockpile, grazing annual cover crops prior to a cash crop, or seeding annuals in the warm season, when cool-season plants decline. Think of cool-season annual grasses such as ryegrass and cereal grains, forage brassicas such as kale, rape, and turnips, warm-season annual grasses such as sorghum-sudan hybrids, pearl millet, and corn, or legumes such as Austrian winter pea (cool-season) and forage soybeans (warm-season). In addition, stockpiling pastures such as bermudagrass, tall fescue, and reed canarygrass can add months of grazing when the grasses go dormant. A diversity of crops and pasture species provides forage for grazing livestock for more of the year, and feeds the soil microorganisms that drive nutrient cycling. For more information on grazing for a longer portion of the year, see Extending Grazing and Reducing Stored Feed Needs, a Grazing Lands Conservation Initiative publication listed below in the Resources section.
Finally, a grazing plan will result in a grazing schedule. A schedule allows you to chart the grazing events visually for each management unit throughout the season and over the years and, when used with a monitoring plan, can assist in refining and adapting the grazing system over time. A grazing schedule can serve as a summary of all management activities and monitoring conducted on each pasture.
Some of the items you might incorporate in a schedule include the following:
Developing a grazing schedule will be discussed below in the writing the grazing plan section. But first, as with any good plan, you should take stock of your assets. This will be discussed below in the resource assessment section.
You'll need to have an idea of your goals and farm assets to write and implement an accurate grazing plan. Assessment should be an ongoing endeavor, beginning with an initial inventory and then adjusting periodically through monitoring to fine-tune your plan. This will help you become more accurate at managing grazing.
Start with your farm goals. What are your overarching purposes? What do you want to get out of your whole-farm plan? Perhaps you are interested in conserving sensitive areas, or renovating poor-performing soils. Write these down and mark them on a farm map. Maybe you would like to increase the diversity of pasture-plant species composition, or maximize animal production. And don't forget marketing. How will you sell your animals or products? What is the yearly schedule for this and how does it affect the seasonal flow of tasks and management events such as calving, lambing, or weaning? What effect do these events have on your pasture needs? Think about your financial goals. What in your grazing plan costs money, and what will make you money? How can you become a more efficient grazier so you can minimize costs while maintaining an adequate cash flow? And finally, what about estate planning and succession? Do you have a plan for transferring the farm to a family member or selling to another farmer when you have finished your farming career? How will you involve them in your plan so they understand the natural-resource carrying capacity, the soil types, the grazing system, and the markets?
Next is a resource inventory. Here you will list the numbers of various classes of livestock currently on the farm. Include potential numbers for the future in order to achieve farm/ranch goals. Animal numbers should include brood cows, bulls, calves, yearlings, replacement heifers, ewes, lambs, horses, etc., and must also include the weights of the animals in order to match forage resources to animal demand.
You'll also want to provide details on the forage resources of each paddock or pasture on the farm. List your total acreage, annual precipitation, precipitation in a drought year, irrigation if any, a basic description of your soils and any soil problems, and your average annual forage productivity. Consider documenting any weed problems, critical areas, and general observations that you have on your pastures. This will help you as you review your grazing plan each year to assess its efficacy.
Once you have your resource inventory, you're ready to write your grazing plan.
There are several tools in the Workbook that will help you write your grazing plan. Here you'll find the following instructional worksheets:
Your grazing plan will detail, in one place, the elements of your farm that make up your grazing system. The Grazing Plan Template was developed to assist you in doing this. You can use it to record your farm description, your goals, your resource inventory (landscape, livestock, and infrastructure), and your grazing calculations to balance forage with animal demand. Other elements can be included, such as your weed plan and how you will manage drought and periods of low forage productivity.
Farm description: Record basic farm information that matters to your grazing enterprise. This is a go-to source for planning your grazing season year by year, and includes space to document your farm name and location, climate (mean annual precipitation and air temperature and rain and dry season, first frost, last frost, frost-free days), grazing-season length, soil types, and predominant pasture species.
Goals description: Record the goals for your operation, including leadership structure, conservation goals, pasture goals, animal goals, financial performance goals, and marketing goals.
Resource inventory: Document your inventory for land, livestock, and infrastructure. Important items are a record of forage demand of livestock in pounds of dry matter per head per day, and an estimate of the amount of forage available.
|Sample forage inventory
Forage/animal balance: Document how you will allot your forage resources to animal needs. This is accomplished by simple grazing calculations to match forage resources to animal demand. Forage productivity in each pasture is averaged and matched with animal demand to determine the amount of use of the grazing resource and to plan for sustainable grazing in the future. The length of your rest period and paddock grazing periods will determine the number of paddocks in your pasture.
|Sample forage/animal balance
There are many tools available to help you plan and monitor your grazing system. What is most important, though, is that the tool be simple and accessible, so that it is easy to use. And if all of your information is available in one place, so much the better.
One method that meets these criteria is a grazing chart. One of the most notable is the grazing chart developed by Troy Bishopp, a New York grazing specialist and contract grazier, which offers graziers the ability to track grazing each day. There is plenty of room on the chart to record production information, weather and precipitation, recovery periods, or anything else that you think important to track.
|Sample grazing chart. Courtesy of Troy Bishopp
The grazing chart is a tool that can be customized based on your own goals, constraints, and needs for documentation and recordkeeping. You can choose the events, indicators, and management tasks that are most important to you, such as animal weights, breeding, calving or lambing, grazing days, paddock recovery period, rainfall or snowfall, temperature, forage yield, forage residual after grazing, and monitoring data, just to name a few. Pasture monitoring is particularly important, because the information obtained will inform grazing planning for subsequent grazing seasons... thus giving you a feedback loop to validate and update your grazing calculations.
By this time you've got a sense of the concept of planned grazing. You've conducted a resource assessment and have gotten an idea of how much forage you have and how many animals it will support. You've also developed a schedule for grazing to allow for pasture recovery and have a plan for how you will rotate livestock through your grazing system. Now, it's time to look at the mechanics of grazing and how to get set up.
Pastures should be divided into paddocks that will serve as grazing units, where livestock will graze a specific amount of forage (based on their demand) for a specific time period. The actual number of paddocks and their associated grazing times will be determined by the paddock recovery period. The shapes of the paddocks will depend on many factors. Topography, water sources, roads, grazing access lanes, and existing fencing are potential obstacles to overcome. You'll need to get a map of your farm to best plan out your paddock sizes and shapes.
Maps can be obtained from your local NRCS conservation planner, or you can search for your farm on a mapping program such as Google Maps. Print the map and walk your fields, taking note of obstacles, fencing, and ease of access. Make sure the animals have access to working facilities, the milking parlor, water sources, and shade. If shade is a limiting factor, portable shade units can be employed. Keep in mind, however, that this will influence manure and urine distribution; hence pasture fertility. For more on this, refer to the fertility lesson in the ATTRA Managed Grazing tutorial.
Square paddocks work well for encouraging uniform grazing. Long, narrow paddocks may not work very well because livestock tend to graze one end of the paddock more intensely, but with high stock density (100,000 pounds or more of live-animal weight per acre), livestock will usually graze an odd-shaped paddock from one end to the other with no problems. In general, maintaining high animal density encourages more uniform grazing. In addition to efficient forage utilization, high stock density also allows for uniform urine and manure distribution, enhancing soil fertility.
Dividing paddocks will necessitate some kind of fencing. You likely have existing perimeter fencing and maybe even a few divided pastures you can start with. Ensure your perimeter fencing is more than adequate to keep livestock out of roadways, streams, and the neighbors' fields. High tensile fencing or even 12.5-gauge, two-point barbed wire work well for cattle, and woven wire for sheep. The internal fencing that will divide your paddocks is much simpler and less costly.
Poly tape, poly wire, poly nets, and cable are the typical choices of graziers for subdividing pastures. Missouri NRCS has an excellent publication, listed in the Resources section, that describes each type and provides guidelines for installation and maintenance. For information on grazing system design, paddocks, and fencing, see the ATTRA publication Paddock Design, Fencing, and Water Systems for Controlled Grazing.
Water is the most important nutrient for grazing animals. Without access to clean water, protein, carbohydrates, and minerals will not be metabolized by the animal. Within a planned, rotational grazing system, water access is a serious logistical consideration.
The considerations for water delivery are placement, distribution, quantity, and materials. Watering points should be easily accessible and easy to maintain. Ponds and stream access points are the simplest sources of water and, if protected with livestock access controls, can be a good source of water. But ponds and streams are often not accessible from all the paddocks when the pasture is divided into multiple paddocks. Some way of delivering water to each paddock is necessary.
Some graziers will provide one or more water-access points for an entire subdivided pasture. A laneway is constructed with fencing from the watering point, usually a central area, to the paddocks. In this arrangement, livestock will travel from the paddock to the watering point several times a day. If this arrangement is chosen, you'll need to make sure the water trough is large enough to accommodate all the animals at once. Because of herd instinct, animals will usually travel in groups to water if it is not located within about 300 feet of the farthest point of the paddock.
If you can place water in each paddock, so much the better. This will reduce the herd-instinct behavior of traveling to water as a group, as water is much closer to the animals. Livestock will travel to water individually as needed, and this not only reduces competition at the watering point but allows you to use a much smaller tank.
An example of a simple watering system, from ATTRA specialist and sheep rancher Dave Scott, is to use 1¼- to 2-inch black poly piping, laid out along the fence lines. Quick disconnects can be placed at any time at strategic points for a water tank or trough with a float valve. With this system, a 150- to 200-gallon tank will provide 35 to 50 cows with adequate water. Each paddock can have a tank, or tanks can be moved across the fence line each time the animals are moved to the next paddock.
So, how do you get started? Really, managed grazing is mostly execution, observation, and adjustment. This is why monitoring and recording grazing data are so important. They give you the ability to capture information and adjust based on what's happening in the paddocks. Make good use of a grazing chart or notebook to record your observations and your monitoring. We'll discuss more about monitoring later, but for now we will begin at the beginning... in the spring when the grass starts to grow.
Now that your pastures are divided into paddocks based on recovery period and number of animals, we can begin when the grass is established and at the three- to five-leaf stage. For cool-season grasses like orchardgrass and fescue, graze quickly through the rotation at first, with a recovery period of around 20 days. This will allow you to keep up with grass growth and ensure that the grasses recover and tiller, making them more productive and getting them firmly established for later in the season when it gets warmer and dryer. Then, as the summer sets in and the temperatures increase, lengthen the recovery period to 30 days or more, depending on your regrowth potential. Make sure your grazing period is short enough to leave a residual of 50% of what you start with. A good guideline is 3- to 4-inch residual for perennial ryegrass and about six inches or more for other cool-season grasses. We all tend to graze too short. Grazing too short markedly reduces leaves and roots, reducing the ability of the pasture to grow back fast and provide carbon nutrients to soil microbes.
For warm-season grasses like bermudagrass and bahaigrass, start when the grass has greened up and make your recovery period between 25 and 30 days. These grasses can take more defoliation, but be sure to leave a residual of at least two to three inches so the plant can capture sunlight and adequately regrow. If you're grazing native warm-season grasses like Indiangrass, bluestem, or switchgrass, make your recovery period about 40 days and make sure you graze them no shorter than about six inches.
For annual grasses like oats, ryegrass, and wheat, graze heavily in the spring to keep them vegetative as long as possible and provide enough defoliation to remove all the biomass, especially if the annual grass was overseeded on a warm-season perennial pasture. This will allow the warm-season grasses to get off to a good start when the annual grasses are done. Warm-season annuals like sorghum-sudan should be grazed when they are about 18 to 24 inches tall, and the animals moved off when these grasses are about five to six inches tall. Many graziers get several successive grazing events with sorghum-sudan, using a rotational or strip-graze system. Sorghum-sudan, a warm-season annual grass, makes a great, high-quality forage, especially when cool-season pastures slow down in the summer.
Other options for grazing include forage brassicas such as kale, rape, and turnips; legumes such as Austrian winter pea (cool-season) and forage soybeans (warm-season); and stockpiled bermudagrass, tall fescue, and reed canarygrass for grazing well into December and January. Be mindful that brassicas are not recommended to be grazed without complementary forages such as oats, barley, cereal rye, vetch, or some combination of other species. Brassicas can cause nitrate poisoning when grazed as a monoculture. They are also non-mycorrhizal, so you are doing your microbes no favors by planting them alone. Extending the grazing season with these options will reduce your feed bill and can fit nicely into your grazing rotation.
When you make your paddock moves, remember that your grazing period—the amount of time the livestock spend on a paddock—should be timed such that it prevents grazing of forage regrowth. Since plants may have enough grazable regrowth two to three days after defoliation, most intensive graziers use this as a rule of thumb for grazing period. Short grazing periods also ensure intake of higher quality forages, which is why dairy graziers often have grazing periods of a day or less.
Finally, there are some rules of thumb for adapting as the season progresses. You can be sure you'll have periods of low precipitation, high temperature, or extreme weather. So, for periods of low forage growth, you should slow down the rotation. This will give you a longer recovery period. This requires planned supplemental pastures or stored-forage feeding. For periods of rapid forage growth, you can speed up the rotation in order to keep up with productivity and not let the forage get too mature and indigestible. Another option for rapid-growth periods is to make hay. However, remember that making hay removes nutrients so that they do not get cycled back into the system. Fields that are hayed year after year will decline in productivity.
Monitoring is often the most neglected part of pasture management. However, it's crucial to maintaining a well-functioning grazing plan. A good monitoring system will allow you to check how your management decisions are working on the ground and will allow you to determine if a particular grazing plan is having the desired effect over time. Monitoring helps you update your grazing calculations on a seasonal and yearly basis.
Research has shown that monitoring pasture gives farmers a planning orientation, sets a baseline of data from which to make planning decisions, and tracks ecological changes due to management and weather events (Sanderson et al., 2009). Farmers who maintain a simple pasture-monitoring program will see benefits, especially in identifying areas that need improvement, selecting land-improvement practices, and obtaining information on yields and productivity to inform future grazing planning.
A monitoring plan will often involve a few important evaluation criteria, such as plant species composition and percent cover. By comparing measurements and key indicators over time, you can start to see trends. And by comparing them to your grazing system, you can alter and adjust as needed in order to arrive at your goals.
Monitoring pastures—in addition to animal productivity and health—gives you a more holistic picture of what's going on in a grazing system. Animal performance will decline after forage resources have been degraded, and pasture and soil health are not always evident if livestock productivity is the only indicator monitored. By monitoring pasture health, you can identify and correct problems before they get too bad and negatively affect animal performance and pasture ecology. A basic pasture-monitoring program will look closely at forage use, pasture and/or paddock use, problem and critical (ecologically sensitive) areas, and changes in management. The three areas of monitoring include observing, collecting data, and keeping records.
There are three areas where monitoring will be crucial for planning and adapting your grazing system seasonally and annually. Here we will cover simple monitoring ideas for these three areas:
Soil is the basis for maintaining sustainable production over the long term. The microorganisms in the soil provide hospitable habitat for a diverse array of soil organisms and make nutrients available for plants and animals. Monitoring soil health is an important way to discover how your grazing system is affecting—positively or negatively—the soil habitat and the biology it supports.
You can easily monitor your soil health periodically. Two instant, revealing tests you can do in the field are a shovel test and a filtration/slake test. The Monitoring Checklist, Appendix E, has detailed instructions on these simple tests. Also, consider sending soil samples to a biological lab that assesses the microbiological activity in the soil. The Monitoring Checklist includes some labs and tests that will help you assess the biological health of your soils.
Monitoring forage production is simple and yields some good information to help you (1) assess the productivity of your forages to help match them to animal needs, and (2) obtain feedback on how well your estimates of forage productivity and quality matched the animal demand for the grazing season. This allows you to adjust and refine your grazing calculations to better reflect the actual amount of forages you have. Some simple techniques for forage monitoring are covered in the Monitoring Checklist and in the Resources section of this manual.
One of the best ways to monitor forage productivity is to clip and weigh forage from your paddocks periodically. You can do this yearly on a few paddocks just to get a baseline and assess changes over time. You can also use a ruler or grazing stick to measure forage height and estimate yield accordingly. For more on forage assessment see the Grazier's Math and the Clip and Weigh Forage Measurement worksheets.
This manual has provided you with the basics of how to write your own grazing plan, from the principles of grazing management to resource assessment and to matching animal demand with available forage. Resource assessment and monitoring are of utmost importance, and we've discussed some methods and resources to help you get started.
The Appendices to this manual are useful checklists and guides. Managed grazing can seem daunting, but it can be tackled easily, one step at a time. Use the Grazing Plan Checklist and study the helpful guides attached as appendices. Then do a thorough farm-resource assessment. This will give you the data to work through the calculations (see the Grazier's Math: Matching forage to animal demand worksheet or the Grazier's Calculator). Then you can develop your grazing schedule and a simple monitoring plan. Expect to make some mistakes: all graziers have and do. Monitor to find the root of the problem and then modify your grazing to correct it. Grazing is a very dynamic business—constantly adapt to what you observe and you will be successful!
Pasture monitoring at a farm scale with the USDA NRCS pasture condition score system.
Sanderson, M.A., S.C. Goslee, J. Gonet, and R. Stout. 2009. Journal of Soil and Water Conservation. November/December.
|Related ATTRA publications
|Managed Grazing Tutorial|
|Grazing Calculator: Extended Cow Calf Pair|
|Integrating Livestock and Crops: Improving Soil, Solving Problems, Increasing Income|
|Irrigated Pastures: Setting Up an Intensive Grazing System That Works|
|Paddock Design, Fencing, and Water Systems for Controlled Grazing|
|Pasture, Rangeland, and Grazing Management|
|Why Intensive Grazing on Irrigated Pastures?|
Grazing Calculator: Extended Cow Calf Pair Pair
ATTRA spreadsheet. 2013. By Dave Scott. National Center for Appropriate Technology, Butte, MT.
ATTRA spreadsheet. 2017. By Dave Scott. National Center for Appropriate Technology, Butte, MT.
Intensive Grazing: One Farm's Setup ATTRA video
2014. By Dave Scott.
Irrigated Pastures: Setting up an Intensive Grazing System That Works
ATTRA publication. 2013. By Dave Scott. National Center for Appropriate Technology, Butte, MT.
Get a printed copy by calling 800-346-9140 or download it free from the ATTRA website.
Managed Grazing Tutorial ATTRA tutorial
By ATTRA Agriculture Specialists. National Center for Appropriate Technology, Butte, MT.
Electric Fencing for Serious Graziers. [PDF]
2005. USDA Natural Resources Conservation Service, Missouri. Download in PDF or order from:
601 Business Loop 70 West, Suite 250
Columbia, MO 65203
Topics include selecting an energizer, grounding, selecting wire, temporary fencing, gates and braces, tools, safety, and troubleshooting.
Extending Grazing and Reducing Stored Feed Needs. [PDF]
2008. By Don Ball, Ed Ballard, Mark Kennedy, Garry Lacefield, and Dan Undersander. Grazing Lands Conservation Initiative.
Extending the grazing season and reducing the need for stored feed is highly desirable. Though the best techniques to accomplish this vary with geographic region, type of farming operation, and other factors, this publication outlines strategies that can be used in some or many areas to extend grazing and reduce stored-feed needs, thus increasing profit.
Fence Systems for Grazing Management 1: Electric Fence Energizers [PDF]
No date. By James R. Gerrish. In: Beef Cattle Handbook. Extension Beef Cattle Resource Committee. University of Wisconsin-Extension, Cooperative Extension.
This chapter deals with fence energizer selection and proper installation. Fencing materials and construction are covered in individual sections in this manual.
Grazing Systems Planning Guide [PDF]
2000. By Kevin Blanchet, Howard Moechnig, and Jodi Dejong-Hughes. University of Minnesota Extension Service. Publication No. BU-07606.
This guide discusses the components of a grazing system by taking you through the grazing-management planning process. Information on grazing resource inventory, plan development, pasture management, and system monitoring is provided.
Pastures for Profit: A Guide to Rotational Grazing [PDF]
2002. By Dan Undersander, Beth Albert, Dennis Cosgrove, Dennis Johnson, and Paul Peterson. Cooperative Extension Publishing, University of Wisconsin-Extension.
To produce good livestock feed from pasture, we must manage our pastures differently. This bulletin outlines an alternative: rotational grazing. By using rotational grazing, you can make a profit from pastures. This bulletin covers the basics of setting up a rotational grazing system on your farm.
Understanding Forage Quality [PDF]
2001. By Dr. Don Ball, Dr. Mike Collins, Dr. Garry Lacefield, Dr. Neal Martin, Dr. David Mertens, Dr. Ken Olson, Dr. Dan Putnam, Dr. Dan Undersander, and Mr. Mike Wolf. American Farm Bureau Federation, Park Ridge, IL.
Information about forage quality and forage testing that can be used to increase animal performance and producer profits.
Watering Systems for Serious Graziers [PDF]
2006. USDA Natural Resources Conservation Service, Missouri. Download in PDF or order from:
601 Business Loop 70 West, Suite 250
Coumbia, MO 65203
Topics include livestock water needs, water sources, delivery systems, tanks, protecting watering areas, tank location, installing pipes, and spring water development.
By Troy Bishopp. The Grass Whisperer Blog.
Developed by a project funded by Northeast SARE, Troy's grazing charts will help you tailor planning and recordkeeping to your own operation. There are several versions available based on your needs. Download, print, and take it to your local copy shop to have it enlarged to hang on your wall.
The New Grazing Charts Are Here
By Kathy Voth. On Pasture.
Excellent instructions for downloading and using Troy Bishopp's grazing charts, including examples and links to articles by Troy.
An online livestock and forage inventory and tracking tool.
Ranch-management software app that allows you to plan pastures and subdivisions, water-tank placement, gates, and monitoring points; record herd data; plan your paddock moves; track forage utilization; and upload photos for forage inventory.
Bullseye! Targeting Your Rangeland Health Objectives [PDF]
2013. By Kirk Gadzia and Todd Graham. Quivira Coalition, Santa Fe, NM.
A simple, non-technical manual to help ranchers establish their own monitoring program in grasslands, shrublands, and grass/shrub mixes.
Pasture Condition Score Sheet [PDF]
2001. By Dennis Cosgrove, Dan Undersander, and James Cropper. USDA NRCS – GLCI.
Scoresheet and instructions for use with the Guide to Pasture Condition Scoring.
An expanded list of soil health tests and procedures you can perform on the farm, including measuring soil quality, infiltration test, bulk density test, aggregate stability test, slake test, water quality tests, and more.
Estimate animal forage demand: Species dry matter intake per day (as a percent of body weight):
Example, a 1050-pound beef cow has a DMI of: (1050 X 0.03) = 31.5 pounds per day
Estimating forage productivity: estimating forage production in pounds per acre per day.
You can estimate forage production with the clip-and-weigh method (see Clip-and-Weigh Forage Measurement worksheet), or you can estimate forage available by hay yield on a pounds-per-acre basis. If your spring hay harvest is 1.8 tons per acre, multiply 1.8 by 2,000 and divide by the number of days between hay cuttings.
Example: 1.8 X 2,000 = 3,600 ÷ 35 days = 103 pounds per acre per day
Knowing the amount of forage your paddocks produce in pounds per acre per day during each season of the year (for example, May to June, June to August, etc.) will help you adjust recovery days, grazing days, and paddock number or size throughout the grazing season.
First, decide on a recovery (rest) period. This is usually lower in the spring, increases as the summer progresses, and may increase again in the fall for cool-season grasses.
Second, decide on a grazing period, or how long the animals will remain in a paddock before they are moved. Keep in mind, plants begin to regrow after about three days, and this should be the beginning of the recovery period. Use the formula below to determine number of paddocks:
Recovery Period ÷ Paddock Grazing Period +1 paddock
Example: 35 days recovery ÷ 1 day grazing period + 1 = 36 paddocks
Determine paddock size: This is a function of herd dry matter intake of forages (grazing unit demand) relative to forage production. To calculate, multiply the herd intake by days grazed and divide this by forage availability and a utilization rate. Forage utilization is the estimated percentage of the forage sward that will actually be consumed by livestock. A good rule of thumb is 50% (or 0.5), but because intense rotational systems are more efficient, we can increase the utilization to no more than 70% (.07). When using 70 % utilization, it is essential to fully recover grasses before re-grazing. For a way to determine this, see Chapter 2 in the ATTRA video Intensive Grazing: One Farm's Set-Up, at 3:40 minutes.
Example: Assume dry matter demand of forage for 100 cows is 39 pounds per head per day, and forage productivity is 3,600 pounds per acre per rotation.
|3,900 pounds herd intake X 1 day grazing period||= 2.2 acres paddock size|
|3,600 pounds dry matter forage X 0.5 utilization rate|
So, in this scenario, 36 paddocks of 2.2 acres average will support 100 cows with a move every day, giving us a 35-day recovery period. The total acreage needed for this system is 79.2 acres.
The Grazier's Calculator is an easy way to match forage production with animal demand. This spreadsheet will calculate, seasonally, the number of paddocks and average paddock size, total forage production, paddock residual, forage available for grazing per paddock, and forage inventory vs. grazing demand, to tell you if your balance is adequate or deficient. If you choose to use this tool, the values you will need to enter are as follows:
How to use the calculator:
The clip-and-weigh method will allow you to calibrate a pasture ruler or pasture stick. To accomplish this, construct a 2-square-foot quadrant frame from PVC or copper pipe. Each straight edge should measure 17 inches. Randomly throw the frame on the ground and clip all the plants inside the hoop at ground level. Place the clipped forage into a paper sack and repeat the procedure at least nine more times, placing samples in separate paper bags.
|Fresh Weight||Dry Weight||Percent DM||lbs./ac|
10 ounces (285 grams)
|1.5 ounces (43 grams)||15%||2,150|
|Source||Water test results||Capacity (gpm)||Description (source, piping size, distance, locations, etc.)|
|Type||Construction||Charger type and joule rating||Source of equipment||Condition of fencing|
|Animal type i.e. lactating dairy, dairy replacement, cow- calf, feeder beef, finishing beef, ewe- lamb, lambs, etc.||Number of animals||Average weight||Average dry matter demand (lb/day) *|
|Grazing season||Date range||Acres||Forage production in pounds per acre per day||Recovery period in days||Forage production in pounds per acre at turn in
Forage production in pounds per acre per day X recovery period
|Grazing Unit Demand|
|Grazing season||Grazing unit type (Cow-calf, ewes, stockers, etc.)||Dry matter demand per head in pounds *||Number of animals per grazing unit||Dry matter demand per grazing unit (dry matter pounds per day) Pounds dry matter X number of animals|
|Grazing Season||Acres||Number of paddocks Recovery (Rest) Period ÷ Paddock Grazing Period +1 paddock||Average paddock size Acres ÷ number of paddocks||Dry matter forage production in pounds per acre||Forage production per paddock Forage production per acre X paddock size||Grazing utilization 35% to 75% depending on residual goals||Paddock residual pounds Forage production per paddock - utilization||Paddock residual pounds per acre Residual per paddock ÷ paddock size||Forage available for grazing per paddock in pounds Forage production per paddock X utilization||Grazing unit demand||Forage Inventory Vs. Grazing Demand: Adequate or Deficient Forage available for grazing per paddock - grazing unit demand|
Adapted from the Monitoring lesson by Dave Scott, in ATTRA's Managed Grazing Tutorial
For a full monitoring discussion see the tutorial at attra.ncat.org/tutorials.
A monitoring plan is an essential part of a grazing plan, and is a feedback mechanism that will provide you with information on what's going on in your pastures, both from climate and ecological factors as well as management decisions. A good monitoring system will alert you to failure before it is too late and will record successful grazing strategies.
|Excellent||Several inches per hour|
|Good||Three to four inches per hour|
|Lacking||Less than one inch per hour|
|Write the results down in a notebook or spreadsheet and compare over time.|
Grazing Planning Manual and Workbook
By Lee Rinehart, NCAT Agriculture Specialist
Published August 2017
Tracy Mumma, Editor
Amy Smith, Production
Diane Warthen, HTML Production
This page was last updated on: October 18, 2018