Taking Control of Your Drainage System
Transcription
Taking Control of Your Drainage System
Advancing Agricultural Performance® and Environmental Stewardship February 19, 2015 Ames, Iowa Taking Control of Your Drainage System Nathan Utt Ecosystem Services Exchange [email protected] Funded in part by the soybean checkoff Why do farmers install drainage? • Improved plant health • Improved trafficability Drainage can have an impact on water quality Photo courtesy http://www.epicinter.net/typical/ We live and work in a drained landscape. Can we protect water quality while still ensuring excellent conditions for crop production? Ecosystem Services Exchange • Founded in 2010 with the goal of developing market-based solutions to water quality issues • Plan Drainage Water Management and Sub-Irrigation systems • Developing nutrient trading markets in the Midwest • Certified Technical Service Provider for the NRCS www.EcoExch.com Ag Drainage Management Coalition • Industry-led organization addressing water quality and drainage concerns • Work with USDA and universities on research and development of new technologies • Provide training workshops to farmers and contractors www.admcoalition.com Improving Water Quality Improving Yield 1. 2. 3. 4. Saturated Buffers Drainage Water Management Sub-Irrigation Denitrifying Bio-Reactors Saturated Buffers A new approach to water quality Saturated Buffers – They look the same to me… Saturated Buffers – How they work Image courtesy Agri Drain Corp. Saturated Buffer Demonstration Project • 4 states, 15 demonstration locations • ADMC is monitoring – – – – Flow Water Quality (N and P) Soil Parameters Stream bank movement • Over 50% reductions in annual nitrate loss • No direct impact on yield anticipated Will a saturated buffer work on my farm? What does the field need to be like? • Interim NRCS standard 739 – Vegetated Subsurface Drain Outlet • Most important site requirements 1. Buffer strip – grass, trees, etc. 2. Tile main to intercept 3. Hydraulic gradient – someplace for the water to go • Other important factors – – – Soil conditions Buffer dimensions/topography Field Topography Saturated Buffer: Soil Conditions • Soil must allow you to maintain a high water table – Restrictive layer – Avoid sand/gravel lens Buffer Characteristics • At least 30 ft wide • Well established vegetation • Flat along the ditch – Up to 2 ft of elevation change along length of buffer – At least 300 ft long – Longer buffer may be needed for larger tile mains Improving Water Quality Improving Yield 1. Saturated Buffers 2. Drainage Water Management 3. Sub-Irrigation Drainage Water Management Drainage Water Management: How it works Winter Spring Summer Fall Only drain what you need, when you need it! Drainage Water Management An optimum water table Desired water table depth varies throughout the year based on: • Soil type • Crop • Drainage intensity • Planting Date The water table is only elevated if Mother Nature gives you some extra water to catch Drainage Water Management: What it does • Improve crop yield – Less tile flow means more water is left in the field with the crop • Improve water quality – Less tile flow means less nitrate leaving the field • Up to 75% reduction in annual nitrate load – Manage tile flow during manure applications • Other benefits – – – – Create wildlife habitat Flood mitigation Reduce subsidence in muck soils Reduce plugging from iron ochre • It just makes sense! Drainage Water Management: Designed to be different • Works best on flatter landscapes – Control structures required every two feet of elevation change • Existing systems can sometimes be retrofitted • Systems generally need to be designed to be managed Photo courtesy Keith Rowher Sub-Irrigation Sub-Irrigation: Maintaining the optimum water table • • Desired water table depth varies throughout the year based on: − Soil type − Crop − − Planting Date Drainage intensity Water is pumped into the system Sub-Irrigation: How does it work? • Drainage mode – Water table is lowered for better aeration of root zone – Field trafficability is improved Impermeable Layer Sub-Irrigation: How does it work? • Sub-Irrigation mode – Water table is managed at optimum level – Water moves upward via capillary rise, providing roots with a healthy combination of water and oxygen Impermeable Layer Will a Sub-Irrigation system work in my field? The Three S’s • Water Source – Adequate supply during the dry part of the summer • Plan for 2 – 5 gpm/acre – Avoid surface water that contains a lot of sediment • Your laterals will silt in over time • Right Soils – A tight layer that will keep water from moving downward • Good Surface – You will need at least one control structure for every foot of elevation change – Flatter and/or uniform slopes are less expensive than steep and/or undulating ground A Good Surface The flatter the better! Image courtesy Agri Drain Corp The flatter the better! How flat is flat? – 1.0’ elevation change per zone • Can be stretched out to 2.0’ for DWM – Every zone requires its own structure – At least one control structure for every foot of elevation change Image courtesy Agri Drain Corp The flatter the better! Image courtesy Agri Drain Corp What if it’s not that flat? Image courtesy Agri Drain Corp What if it’s not that flat? Image courtesy Agri Drain Corp What if it’s not that flat? Image courtesy Agri Drain Corp What if it’s not that flat? • How much slope is ok? – 1.0’ to 1.5’ elevation change per zone – Every zone requires its own structure – At least one control structure for every foot of change • Uniform slopes can work ok • Undulating ground gets tricky Image courtesy Agri Drain Corp What yield results can I expect? Yield Impact from Drainage Practices • Study of Ohio’s poorly drained soils • Compared to lands with adequate surface drainage, • Subsurface drainage improvements may increase yields by 25-30 bu/ac for corn and 3-12 bu/ac for soybean. • Compared to lands with adequate subsurface drainage, and where conditions are appropriate. • Drainage Water Management may increase corn and soybean yield on average by 7.0% and 3.6%, respectively. • Compared to lands with adequate subsurface drainage, and where conditions are appropriate, • Sub-Irrigation/controlled drainage may increase yields by 25-60 bu/ac for corn and 9-12 bu/ac for soybean. Ohio State University/USDA-ARS Crop Yield Data Sub-Irrigation Yield Impact: Fulton County, OH 250 Yields are more consistent Corn Yield (bu/ac) 200 150 100 Dry summer 50 0 1994 1996 1998 2000 Sub-Irrigation 2002 2004 2006 2008 Drainage Only J. Allred et al, Crop Yield Summary for Three WRSIS in NW Ohio. Applied Eng. in Ag. Vol. 30(6):889-903 2010 Sub-Irrigation Yield Impact: Missouri clay-pan soils Yield increase over non-drained control Year(s) and Environment DO 20’ DSI 20’ ---Bu/acre--- DO 20’ DSI 20’ --------%-------- 06: Dry-Moderate 8 72 6 55 02,05,12,13: Wet-Dry 14 70 22 108 03,07: Wet-Moderate 26 56 25 48 04,08,09,10,11: Wet-Wet 35 31 25 22 Average 20 57 20 58 DO = Drainage Only 2004-2005: PCU, Irrigation, Drainage on NU and Yield. Nelson et al., 2009. Agron. J. DSI = Drainage and Sub-Irrigation 2006-2007: N Source & IWMS on Yield Nelson and Motavalli, 2014. App. Eng. in Agric. 2008-2010: IWMS and High Yield Hybrids Nelson et al., 2012. Intl. J. Agron. Slide courtesy Kelly Nelson, 2014 Drainage Research Forum. Ames, IA Wrapping things up… • Saturated Buffers – New practice for improving water quality • Drainage Water Management and Sub-Irrigation – – – – Improved and stabilized yields Improved water quality Remember the three S’s Source, Soils, Surface • Designed right • Installed correctly • Managed properly Questions? Nathan Utt Agricultural Engineer Ecosystem Services Exchange [email protected] 402-405-3995 Image courtesy Keith Rohwer Sub-Irrigation: Automated Control • Automated control structures for managing water levels • Integrated pump controls • Web access for remote monitoring and control Products provided by