1. Understanding The Water Budget at Soaring Eagle Dairy - 4 Understanding Surface Water Runoff at SED Eric Cooley and Dennis Frame UW Extension/Discovery Farms
2. Data The data presented in this presentation were provided by the U.S. Geological Survey as part of a cooperative agreement with the UW-Discovery Farms Program.
3. Water budget Monitored from Dec. 2004 - Oct. 2006 Field year = 12-months (Nov. 1 – Oct. 31) Always represents the year in which it ends Field year coincides with the crop year.
4. 2005 Field Year The first year November 2004 – October 2005 = drought year. Precipitation (ice, sleet and snow) was 21.7 inches, compared to the 30-year average of 30.5 inches for Manitowoc County.
6. 2005 Field Year However, the winter period (December through March) had a number of runoff events. This occurred because a significant amount of rain (5.1 inches) fell on snow covered/frozen ground.
7. 2005 Field Year Surface water began flowing December 2004 after rain events including 0.63” on 12/7 and 1.19” on 12/9-10 . Water flowed through December into January, even after air temperatures dropped below freezing and precipitation had ended. The prolonged surface runoff during below-freezing air temperatures was surprising.
8. 2005 Field Year Typically in watersheds, runoff exhibits a rapid response to rain or melting snow, and then over a relatively short period of time (minutes to hours) the flow greatly diminishes and stops. Discovered that the majority of runoff appeared to be coming from subsurface tiles that emptied into the waterway above the monitoring site.
9. 2005 Field Year Concerns about the influence of tile on runoff include: Much of the area drained by this tile was not under SED control - land and management practices were unknown Drainage area for this tile was unknown Some of the tile systems contained surface inlets, which greatly increase the potential for nutrients and sediment to run off into the site.
11. Extended flow and freezing temperatures caused the runoff to freeze downstream of the site. Pools formed causing an ice dam. Once established, water filled the flume with ice. Discharge measurements could not be considered accurate, so samples were not taken.
12. Flume remained encased in ice until early March. After the ice was removed, debris remained downstream causing water to backup during surface water events. Temporary fixes and lower surface water runoff volumes allowed accurate flow measurement and water sampling to resume in early April 2005.
13. 2005 Field Year No data were reported between mid-December 2004 and mid-March 2005. Runoff volumes and the associated nutrient and sediment losses reported for the 2005 field year are greatly underestimated and should not be used, or used with caution.
14. 2005 Field Year To improve the site, the waterway was re-graded to create better getaway conditions.
15. 2006 Field Year Second year was much different than the first. 37.1” precipitation (ice, sleet, & snow) > 6” above the 30-year average Majority recorded in the spring (May 7.1”)
17. 2006 Field Year May 12, 2006; ground was saturated. Rains created more challenges: Runoff observed cutting under the wingwall after a 2.5-inch rain event.
18. 2006 Field Year Cutting produced a hole under the wall The hole was filled May 24 with a combination of sand bags and bentonite, stopping the tunneling.
19. 2006 Field Year From May 27 – May 31 the site received nearly 3” of rain, causing significant runoff, and the flume overtopped. Caused significant tunneling
20. 2006 Field Year Runoff volumes for the tunneling periods were estimated by: estimating hole size, flow rate and head pressure; extrapolating the hydrograph from a point where the hole formed; and comparison to hydrographs from other local Discovery Farms sites.
21. 2006 Field Year Although these periods of discharge were estimated and were not as accurate as a typical monitoring station, the runoff amounts and the associated sediment and nutrient losses should be reasonable for the 2006 field year.
22. 2006 Field Year From January 2006 – July 2006, the site flowed a total of 190 days. did not flow 22 days Not typical for surface water driven sites Provides proof of significant impact of tile discharge. Upstream tile contributed significant portion of the flow
23. 2006 Field Year 2006 had significantly more precipitation than 2005 37.1 inches versus 21.7 inches 18% (6.6”) ran off the field
24. 2006 Field Year Majority occurred in the spring when soils were saturated
26. Conclusions Tiles draining into the waterway contributed a significant amount of runoff water to the basin. Conclusion based on the larger than expected flow volumes and the long duration of the flow through the monitoring station. In Eastern Wisconsin tile drainage systems are common.
27. Conclusions Tile drainage greatly influenced surface flow. Caused waterway to behave more like an intermittent stream To accurately monitor a stream, a more permanent structure (concrete or sheet piling) needs to be constructed and flume-sizing may need to be increased in these landscapes due to the larger flow of water.
28. Conclusions When monitoring surface water on cropland with tile drainage systems, it is important to accurately identify the tile drainage area. Tiles can drain water from fields outside the watershed (as identified by slopes) and empty into streams or waterways. This is often the case for fields that are internally drained (closed depressions).
29. Information Available This presentation is the fourth in a series of six developed to provide the data and information collected at Soaring Eagle Dairy. All of the presentations, factsheets and briefs are available on the UW - Discovery Farms website.
30. Information Available There are six factsheets available on SED. There are six briefs available on SED (2 page summaries of the factsheets). There are six presentation available on SED.
31. For Additional Information http://www.uwdiscoveryfarms.org UW Discovery Farms 40195 Winsand Drive PO Box 429 Pigeon Falls, WI 54760 1-715-983-5668 jgoplin@wisc.edu or drframe@wisc.edu