The Wright SWCD applied for, and received, a Soil Erosion and Drainage Law Compliance grant in 2015. This grant was used to inventory Joint Ditch 15 (JD 15) for areas that could benefit from the installation of Side Inlet Control Structures (SICS) and vegetated buffer strips (buffers). JD 15 is known to have areas of significant erosion that effect both benefited landowners as well as a number of impaired waters downstream. The impaired downstream waters include Sucker Creek, Cokato Lake, and the North Fork Crow River. The JD 15 Inventory was completed during the summer of 2015.
This project will work with the MPCA to conduct watershed pollutant load monitoring at four sites in the Chippewa River watershed and one site in the neighboring Pomme de Terre River watershed . The Chippewa River Watershed Project (CRWP) team will also aid the MPCA in measuring and comparing regional differences and long-term trends in water quality. The goal is to collect quality data and complete load calculations for the five sites using the MPCA's established protocols.
The goal of this project is to collect data, water chemistry and field parameters, which will be paired with biological data collected by the MPCA to assess water quality conditions at seven sites along targeted reaches within the Snake River Watershed and five sites in the Two River Watershed.
This project will address nutrient impairments of the Sauk River and Sauk River Chain of Lakes (SRCL) by minimizing runoff from 5 high priority feedlots. Specifically, contaminated runoff from 5 feedlots upstream of the SRCL will be eliminated. The sites were prioritized based on the Minnesota Feedlot Annualized Runoff Model index ratings and the location of these feedlots are within a Drinking Water Supply Management Areas.
A collaboration between the Roseau County SWCD and the Roseau River Watershed District (RRWD), the CD 8 Subwatershed Sediment Reduction Project will reduce sediment delivery to the Roseau River by implementing Best Management Practices on sites that have been identified as the greatest contributors of sediment. Sites were prioritized based on modeled data from the Watershed District's Site Prioritization Grant, and the International Watershed Institutes's Water Quality Decision Support Application (WQDSA) and local knowledge of the subwatershed.
The Accelerated Water Quality Project Implementation Program will increase the connection between landowners, local government units and the landscape to accelerate efforts addressing non-point source loading to surface waters throughout the Red River Valley Conservation Service Area.
The Stearns County Soil and Water Conservation District will hire an Accelerated Water Quality Technician to focus on projects in the Middle Sauk area showing the greatest pollution reductions. After identifying and prioritizing targeted sites with the highest pollution potential, the Stearns County SWCD will begin surveys and designs and complete them in a timely fashion while current implementation funds are available. The accelerated survey and design in Stearns County will relieve our natural resources of the current strain put on them by the environment and land use.
The AgBMP Loan Program provides needed funding for local implementation of clean water practices at an extremely low cost, is unique in its structure and is not duplicated by any other source of funding.The AgBMP loan program provides 3% loans through local lenders to farmers, rural landowners, and agriculture supply businesses.
The Wright County Soil and Water Conservation District (SWCD) will implement a targeted fertilizer application program in the Ann Lake watershed, allowing producers to measure soil fertility and apply needed fertilizer more accurately, preventing over-application and consequent runoff of nutrients, especially phosphorus, into surface waters. Phosphorus reduction will help meet the goals of the County's Water Management Plan and the TMDL implementation plan for Ann Lake.
This project will provide condition monitoring and problem investigation monitoring at the following sites.
Mississippi River: Tributaries include Bassett Creek, Cannon River, Crow River, and Minnehaha Creek.
Minnesota River: Tributaries include Eagle Creek,Riley Creek, and Valley Creek tributary to the St. Croix River
The Ashley Creek and Adley Creek Inventory Project will involve desk top analysis and a field scale inventory of riparian areas to determine priority areas to install erosion control Best Management Practices and vegetative buffers for nutrient reduction. Assessments will also be made for potential E.coli bacteria sources. Inventory data will be shared with local partners to further develop an implementation plan to address nutrient loading and the listed impairments on each creek.
Funds are to be used to protect, enhance and restore water quality in lakes, rivers and streams and to protect groundwater and drinking water. Activities include structural and vegetative practices to reduce runoff and retain water on the land, feedlot water quality projects, SSTS abatement grants for low income individuals, and stream bank, stream channel and shoreline protection projects. For the fiscal year 2012, BWSR awarded 12 local governments with funds.
Funds are to be used to protect, enhance and restore water quality in lakes, rivers and streams and to protect groundwater and drinking water. Activities include structural and vegetative practices to reduce runoff and retain water on the land, feedlot water quality projects, SSTS abatement grants for low income individuals, and stream bank, stream channel and shoreline protection projects. For the fiscal year 2012, BWSR awarded 13 local governments with funds to complete 143 projects. More information is available in the detail reports below.
In 2002, citizens began to notice severe algal blooms in Cedar Lake, a high value recreational lake with exceptional clarity and fisheries habitat. Clearwater River Watershed District (CRWD) began an intensive monitoring program in 2003 to identify nutrient sources and protect Cedar Lake. Through intensive lake and watershed monitoring, CRWD identified the major source of nutrients to the lake. Three nutrient impaired shallow lakes; Swartout, Albion and Henshaw Lakes, in the upper watershed and impaired wetlands discharge excess amounts of soluble phosphorus.
The Chain of Lakes Targeted Reduction project will utilize Clean Water Funds to address bank erosion and install vegetated buffers along tributaries to the Eden Valley Chain of Lakes using the SRWD's incentivized Hayed Buffer Program. The Eden Valley Chain of Lakes (Vails Lake, Eden Lake and North Browns Lake) drain into the main segment of the Sauk River Chain of Lakes (SRCL) from the south. Impaired for excessive nutrients, this southern series of lakes is influenced by inflows from private ditches and perennial and intermittent streams.
This project will complete a comprehensive and sustainable Major Watershed Restoration and Protection Strategies report for the Chippewa River, its tributary streams, and the many lakes in the Chippewa River watershed that is understandable and adoptable by local units of government and residents.
The Villa Park Wetland Restoration Project proposes sediment removal from 6 contiguous stormwater wetland treatment cells within the Villa Park Wetland system resulting in an additional 118lbs/yr of total phosphorus(TP) removal from water entering Lake McCarrons.
The primary objective of this workplan is to demonstrate the ability of the City of Paynesville to meet the current and future wastewater treatment needs and achieve beneficial use of wastewater effluent, to replace the use of groundwater.
The Clearwater Lake Chain has elevated nutrient levels which lead to poor water quality. The City of Kimball and surrounding agricultural area drains, mostly untreated, into a trout stream which empties into the Clearwater River Chain of Lakes.
The goal of this project is to update existing bacteria and Total Suspended Solids (TSS) source inventory through desktop survey and field reconnaissance to identify and prioritize locations to reduce sediment and bacteria loading to the Clearwater River; then, design and implement best management practices (BMPs) at prioritized locations to reduce loading.
The Q-Lot at St. Cloud State University (SCSU) is an 8 acre (1,000 spaces) gravel and asphalt parking lot. The parking lot's surface is impervious, which means it doesn't allow for rainfall or snow melt to soak into the ground. Instead, the water runs off directly into storm sewers, taking with it sediment, bacteria, automotive fluids and other pollutants which flow straight into the Mississippi River. SCSU staff has frequently witnessed plumes of sediment the color of chocolate milk where the storm sewer discharges into the river.
The St. Cloud Waste Water Treatment Facility (SCWWTF) is currently conducting long term planning for future biosolids management. The most likely path forward includes dewatering of the digested biosolids, which will produce a supernatant stream with significant phosphorus and ammonia loads that would be returned to the liquids treatment portion of the WWTF. Returning these nutrient loads to the liquids train would result in increases to effluent concentrations, increases in power consumption, or both.
The City of Cold Spring is looking to retrofit 24 acres of existing development within a 138 acre subcatchment of the City to improve the water quality of Cold Spring Creek, a designated trout stream. The large amounts of hard surfaces within the subcatchment area do not allow for rainfall or snow melt to soak into the ground. The stormwater carries with it sediment, bacteria, automotive fluids, and other pollutants. Cold Spring staff has frequently witnessed sediment plumes, the color of chocolate milk, at the storm sewer outfalls.
On behalf of the Metropolitan Council, Environmental Financial Group Inc. generated a matrix of water conservation programs with detailed information about the costs and benefits of the programs. Tools were also developed to allow users to calculate potential water savings, estimate program implementation costs, and test the effects of various water conservation programs and rate structures.
The Crow River is a major river system in Wright County that is of local and regional significance. It is a major recreation area in its own right but also flows into the Mississippi River 20 miles from the Minneapolis Drinking Water Plant intake. Elevated sediment levels in the river increases the cost of treating the river water and threatens fisheries habitat.
The Wright Soil and Water Conservation District has partnered with the Crow River Organization of Water (CROW) and the Natural Resources Conservation Service on this comprehensive sediment reduction project to focus on stabilizing five of the most active gully erosion sites on the Crow River. A LiDAR study and follow up field inspection identified 15 priority sites within the study area. This particular area was chosen due to the high level of turbidity and low dissolved oxygen within this stretch of the Crow River.
The Wright Soil and Water Conservation District has partnered with the Crow River Organization of Waters (CROW) and the Natural Resources Conservation Service (NRCS) on phase two of this comprehensive sediment reduction project to focus on stabilizing five of the most active gully erosion sites in targeted subwatersheds on the North Fork Crow River, as well as use the installed best management practices to help promote future conservation practices.
The Wright Soil and Water Conservation District (Wright SWCD) has partnered with the Crow River Organization of Waters (CROW), the Natural Resources Conservation Service (NRCS) and Wright County Planning and Zoning on this bacterial impairment reduction project to bring feedlot operations into compliance in the targeted North Fork Crow River (NFCR) impaired Unnamed Creek watershed. An analysis of the NFCR TMDL for Bacteria, Nutrients, and Turbidity was done to determine the area to be prioritized for further review of livestock operations in order to reduce the E.
The Wright Soil and Water Conservation District has partnered with the Crow River Organization of Water and the Natural Resources Conservation Service on phase three of a comprehensive sediment reduction project that focuses on stabilizing seven of the most active gully erosion sites on the North Fork Crow River. These seven areas were chosen due to the high level of turbidity and low dissolved oxygen within that stretch of the North Fork Crow River, which has led to biological and turbidity impairments.
This project will conduct a 2017 revision of the South Fork Crow River, North Fork Crow River and Sauk River Watershed Hydrological Simulation Program FORTRAN (HSPF) models and review of the Pine River Watershed HSPF model.
The project goal is to conduct water chemistry monitoring at five subwatershed sites and two basin sites annually from 2016-2019, based on flow conditions, targeting runoff events using protocols defined in the Watershed Pollutant Load Monitoring Network (WPLMN) Standard Operating Procedures and Guidance. The data collected will be submitted to Minnesota Pollution Control Agency (MPCA) and used in the FLUX32 model for calculating pollutant loads.
The purpose of this project is reduce peak flows in the North Fork of the Crow River through culvert sizing. Culvert sizing will typically result in smaller culverts, which will provide short-term temporary storage within channels and on adjacent lands upstream from road crossings. In addition to reducing peak flow rates, flood damage and downstream erosion, increased sediment and nutrient removal through extended detention time is expected.
This project will directly inform the Lake of the Woods (LoW )TMDL process by identifying nutrient reduction targets, a timeline of phosphorus loadings to the lake, and measures of historical in-lake variability (e.g., nutrients, biological communities). Results will complement and build on ongoing research efforts on internal loading and sediment core analysis.
This project will support the collection and analysis of sediment core samples, from each of the five bays ( Little Traverse, Big Traverse, Muskeg, Sabaskong and 4-Mile Bays), to ensure adequate characterization of the P fluxes from deposited sediment and equilibrium P fluxes from re-suspended sediment.
This project will complete a comprehensive study, following a rational, step-wise process of data analysis, response modeling and comparison to the water quality standards, followed by impairment diagnosis, modeling of improvement and protection options, and development of a WRAP Report and Implementation Plan for Sunfish lake, Thompson lake, Pickerel lake, and Rogers lake.
This project will finalize HSPF watershed model construction by incorporating internal phosphorus loading in modeled lakes, run a suite of implementation scenarios and generate a GenScn project containing model output. The consultant will produce HSPF watershed models that can readily be used to provide information to support conventional parameter TMDLs. The consultant will deliver all modeling files for baseline and implementation scenarios and provide a GenScn project containing model output.
This project will develop and execute three point source related scenarios for the Chippewa River watershed using an existing HSPF watershed model. This project will also support the review of the HSPF Modeling Guidance Document.