Effective Irrigation Scheduling
Having an effective irrigation schedule established for the upcoming season is not only useful to help manage water and pumping costs, but also to help reduce disease, fertilizer use, runoff, and erosion. An effective schedule contributes to healthier turf, greater playability, and more importantly, increased safety. The creation of irrigation schedules have matured in many ways from the old methods of arbitrary runtimes for spray and rotor zones, to utilizing full water audits, soil analysis, and daily, automatic sprinkler run time adjustment for evapotranspiration rates calculated by on-site weather stations. While these newer scheduling methods are more efficient, many turf managers may lack the resources and experience to develop highly efficient irrigation schedules.
Among the variety of solutions for irrigation scheduling are “Smart Controllers” offered by many manufactures that can help assist with daily irrigation scheduling adjustments. Smart controllers are irrigation controllers that have the ability to adjust the daily irrigation run times based on the weather conditions. These smart product offerings vary greatly in cost and complexity. Some manufactures offer simple add-on weather sensors that provide true onsite weather data that may be compatible with existing field controllers. Other more complex solutions may require existing field controllers to be replaced and add monthly subscription costs to supply the daily weather information from distant weather stations to the site. While smart controllers can be useful tools to achieve greater efficiency in irrigation scheduling, they first require an accurate assessment of the site. Another consideration is that weather based controllers often times need significant initial observation and adjustment before optimal performance is achieved.
Another option to assist with irrigation scheduling is the use of moisture sensors. Typical systems utilizing moisture sensors have one or more sensors placed in the root zone of the irrigated area. These sensors will either inhibit or shut down an irrigation cycle once optimal soil moisture levels are present. A simple tool to use as a reference of the level of soil moisture is the tensiometer. These devices are installed in the root zone similar to moisture sensors, but provide a gauge that can be visually referenced for the status of soil moisture.
Regardless of any technologies being employed, it is important to note that having an efficient system is paramount to effectively utilizing your limited water resources. It is a good idea especially on older systems to perform a tune up before addressing scheduling concerns. During this site inspection the system should be checked for damaged and leaking heads and to ensure heads are level and unobstructed. At this time the pressure should also be checked at the nozzle to verify the optimum manufacturer pressure recommendations are met. If the pressure is too high, pressure regulation at the valve should be considered since high pressure can hamper efficiency just as badly as low pressure. If low pressure is observed refer to manufacturers nozzle data. Often smaller nozzles can be utilized to help reduce flow and restore pressure and nozzle efficiency to the system.
An irrigation schedule should be created for each month of the growing season. This will serve as a base schedule which will typically require only minor adjustments with the exception of extreme weather events like prolonged rain or above average heat. The first step in this process is to collect historic or average evapotranspiration rates for the local area. Evapotranspiration is the measured combined loss of water from soils by evaporation and plant transpiration. This data can often be accessed through a water purveyor website or by an internet search for the best available local source. Once this data is gathered, you can derive how many inches of irrigation water is needed by plant type. The irrigation schedule would then be built to replace this lost moisture. An additional consideration of the efficiency of the irrigation system components also plays a role. Since no irrigation system is one hundred percent efficient, additional irrigation will need to be applied to compensate for the difference between the plants needs and the ability of the irrigation equipment to apply the water. As a general rule, rotary sprinklers range in efficiencies from excellent at 80% or higher, to a general average in the 70% range. Spray sprinklers tend to be less efficient than rotary with the high range being 60% and an average around 50%. Many systems with pressure, flow, and maintenance issues can fall well below these averages. Irrigation system audits are highly recommended to understand true system efficiency. Often times, the cost of a full water audit will provide a reasonable return on investment through potential irrigation scheduling water savings.
Soils can be thought of as your water reservoir and soil type plays a significant role in determining how often and to what duration irrigation needs to be applied. For example, sandy soils do not offer as much water holding capacity as a clay soil. However, sandy soils are able to absorb water being applied over a longer period of time before irrigation run off begins to occur. Clay soils are the opposite, and generally require several short sprinkler run times before the desired amount of water is applied to the root zone. Simply running the irrigation system and observing the amount of run time until runoff occurs is a useful way to help determine the length of irrigation run time your soil can handle. An important note to consider when determining sprinkler run times is that soils generally have a high initial intake rate that will drastically decrease, especially as you approach the soils water holding capacity. It is important to keep in mind plant roots do not seek water; rather only grow where water is present and your irrigation schedules should be designed to provide more infrequent, deeper watering cycles. Frequent, short irrigation cycles typically only provide moisture in the first few inches of the soil. This will create a shallow moisture reservoir and lead to shorter root zones and less drought tolerant turf.
As you prepare for your upcoming growing season, assess and repair the irrigation system at spring start up and generate an expected monthly irrigation schedule based on your local evapotranspiration rates. If your budget allows, strong consideration should be made for employing irrigation system audits and new technologies like smart controllers or to help achieve optimum water savings for greater safety and playability.
There are many knowledge bases in the irrigation industry that can assist with the education and consulting of an irrigation system. The following websites offer different educational resources and networking opportunities:
www.irrigation.org (Irrigation Association)
http://www.atinet.org/cati/cit/ (Center for Irrigation Technology, Fresno)
http://www.asic.org (American Society of Irrigation Consultants)
http://www.stma.org/ (Sports Turf Managers Association)
Solar Sync – Smart Control add on’s like Hunter Industries Solar Sync will automatically adjust irrigation runtimes based on-site weather conditions. Solar Sync is easily retrofit table to Hunter’s entire AC powered controller line.
Solar Sync continually gathers solar and temperature data used in the calculation of ET, then determines irrigation watering requirements. Solar Sync automatically calculates these water requirements and makes seasonal adjustments to your controller taking into account on-site weather conditions. During passing or soaking showers, freezing conditions, or sunny days, Solar Sync ensures your system only runs to keep your lawn at peak performance with optimal watering.
I-40 – Rotary Sprinklers like the Hunter I-40 are high efficiency sprinklers, designed for safety and reliability for Sports Fields of all types.
The I-40 is the number one choice for sports facilities worldwide. Ideal for parks and commercial sites, this tough, reliable rotor delivers water with accuracy at distances up to 70 feet. From stadiums to practice fields and other sites, this group performs. Plus, the aesthetic appeal and strength of stainless steel is undeniable. Looking good and built to last, the I-40 is the professional’s choice for ultimate performance, effective irrigation, and beautiful results.
ICV / Accu-Sync– Pressure regulation at the valve can immediately solve high pressure issues that can lower sprinkler performance. These pressure regulators are easy to install and are offered either adjustable or pre-set pressures like in the case of Hunter’s Accu-Sync Pressure regulators.
For a long-lasting valve that can deliver dependable performance at commercial sites, the ICV is the heavy-duty workhorse you can count on. This valve includes both a fabric reinforced EPDM diaphragm, EPDM seat, and flow control as standard features, and can consistently withstand pressures of up to 220 PSI. The ICV also offers the added option of the Accu-Sync™ pressure regulator to maintain a safe, constant water pressure. Plus, it’s exceptionally easy to service, with bonnet bolts that can be loosened and tightened using a variety of common contractor tools.
I-Core – An irrigation controller that is easy to use and has features like cycle and soak, seasonal adjustment, and real time flow monitoring can greatly assist with the implementation of an effective irrigation schedule.
Designed for demanding commercial and high-end residential applications, the full-featured I-Core controller is easy to use, easy to install, and easy to program. The I-Core plastic is expandable from 6 to 30 stations and the metal is expandable to 42 stations. Other features include seasonal adjustment independent by program, which can be set globally, monthly, or through Solar Sync; Easy Retrieve™ Memory to save preferred settings in case of power loss; six language options; and four fully independent programs for customizable irrigation scheduling.
ICR – A great tool for Sports Turf Managers is a hand held remote than can aide in checking irrigation systems for performance issues and conducting water audits.
The ICR has a signal strong enough to go through obstructions such as buildings, walls, or trees and communicate with a controller for a half mile or more. And, when nothing is in its path, the ICR can function up to two miles from the controller. The ICR is a single unit that can be carried from job to job and used to remotely access dozens of diﬀerent irrigation systems.