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Integrating Environmental, Engineering and Constructability Considerations in Wind Power Development. Anntonette Alberti, JD Tetra Tech, Inc. Goals of the Presentation. Provide an overview of the wind generating facility development process
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Integrating Environmental, Engineering and Constructability Considerations in Wind Power Development Anntonette Alberti, JD Tetra Tech, Inc.
Goals of the Presentation • Provide an overview of the wind generating facility development process • Describe the inter-relation of environmental, engineering and constructability data on each phase of wind farm development • Site Screening • Conceptual Design • Final Design • Permitting • Construction • Operations and Maintenance • Stress the importance of designing and permitting constructable and economic wind projects
Site Selection/Screening • Two most basic questions: • Is the site windy? • Is the site near adequate “take away” transmission? • If you pass the basic questions then: • Investigate availability of land • Investigate public and local government acceptability • Investigate environmental and engineering considerations • Critical Issues Analysis • Regulatory Strategy
Critical Issues Analysis • Critical Issues Analysis is a study that: • Identifies conditions at the proposed project site • Identifies likely siting issues • Projects impacts on schedule/budget • Provides management strategies to reduce impacts on schedule/budget • Components include: • Phase I - Desktop studies - Available a la carte (Biological, Cultural, Aesthetics, Geotechnical, Telecommunications, Aviation, Land Use and Permitting, etc.) • Phase II – Reconnaissance-level Field Studies • Critical Issues Analysis Report- Documents key issues that warrant special consideration- Provides: permit matrix, recommendations, and schedule
Common Critical Issues Analysis Omissions • Aviation Screening • Telecommunications Screening • Engineering/Constructability Issues • Steep slopes • Unstable geotechnical conditions • Inadequate work space
Moving on to the Conceptual Layout • You now know you have a potential wind site! • Client should have an idea of the turbine technology that should be used in subsequent studies • Move on to the conceptual layout
What is the Conceptual Layout? • Initial layout that includes turbine locations, access roads, electrical collection system, switchyard(s) and substation(s), transmission lines, O&M building, and construction work areas. • Necessary for obtaining land rights, performing preliminary studies, beginning the regulatory process, etc. • Typically the developer or the meteorological firm will take a first cut at the conceptual layout of turbines on a constraint map.
Defining the Conceptual Layout • Preliminary Selection of Turbine Technology • Important for turbine spacing • Important for defining setbacks • Define Project Constraints • Wind • Land • Setbacks from Homes/Infrastructure • Engineering/Access • Environmental • Cultural • Political • Create Conceptual Layout
Typical Setbacks and Constraints • Setbacks from sensitive buildings such as residences, schools, hospitals and churches; • Setbacks from outbuildings such as barns, garages, and hunting camps; • Setbacks from roads, trails, and recreational areas; • Setbacks from transmission lines, oil and gas wells, oil and gas transmission, gathering and service lines, sub-surface mining operations and other such infrastructure/facilities; • Setbacks from non-participating parcel boundaries; • Wetlands, surface waters, and any regulatory buffers around them; • Sensitive cultural resources and any regulatory boundaries around them; • Locations of special status wildlife or vegetation species and/or critical habitat; • Areas of known geotechnical instability; • Fresnel zones and other communication/radar related constraints; • Areas impacted by air traffic (both civilian and military); and • Any other environmental and land use constraints identified for the site.
Agricultural Siting Considerations • Locate structures along field edges where possible • Locate access roads along ridge tops where possible to eliminate the need for cut and fill and reduce the risk of creating drainage problems • Avoid dividing larger fields by locating access roads along the edge of agricultural fields • All existing drainage and erosion control structures such as diversions, ditches, and tile lines shall be avoided or appropriate measures taken to maintain the design and effectiveness of the existing structures • Minimize loss production, crop damage and top soil
Engineering Tasks for Conceptual Layout • Perform desktop study to evaluate subsurface conditions and geologic hazards • Desktop Transportation Analysis • Initial Road/collection system Layout • Initial Constructability review
Moving from the Conceptual Layout to the Final Layout • Wind projects have a lot of moving parts: wind resource, property, landowner preferences, setbacks, environmental constraints, cultural resources, engineering constraints, transportation issues, constructability, etc. influence where project facilities will be sited • There must be communication among team members and impact on layout must be understood and incorporated • The best team includes a meteorologist, a land man, an environmental scientist, an engineer, a constructability expert, and a lawyer • Data management with multiple team members can be a challenge
What is the Final Horizontal Layout? • This layout depicts all project facilities for permitting and land acquisition purposes • In many cases, permits must be obtained for exactly what will be built, so a certain amount of engineering must be done at an early stage • In a perfect world, micrositing occurs prior to submitting major permit applications and conducting NEPA (or state equivalent) review • Failure to do so often means the need to do permit modifications, supplemental EISs, and/or variances during construction • In the real world things aren’t that simple. • If possible, permit for flexibility
Studies that Support Final Horizontal Layout • Field Studies • Site specific environmental and cultural fieldwork • Site specific engineering field work • Constructability considerations • Adjust Horizontal Layout and Review for: • Wind resource • Constructability • Engineering • Environmental/cultural resources • Land owner acceptability • Final Horizontal Layout
Engineering Tasks for Final Layout • If topo exists, may need to commission a fly-over to perform digital photography from which a topographic base map can be prepared • Perform site walkdown of all project facilities to assess access feasibility (slope and terrain issues, etc.) • Perform geotechnical investigations needed for design of roadway cross-sections, collection system routing and wind turbine foundations
The Timing of Studies • This is the hardest part of advising a wind client • Provide enough preliminary study for siting, but not waste money by providing detailed study on facilities that are not in their final location • If possible, only perform full wetland and cultural delineations on the exact locations of project facilities when they are in their final location • Consider timing when running visual simulation, shadow flicker analysis, writing up noise study, etc. • Because siting is an iterative process, there will always be some inefficiency in study
Transportation Study • Perform traffic and transportation study, for oversized or heavy deliveries, to assess adequacy of existing offsite roadways, bridges, crossings over culverts, overpasses/underpasses, turning radii, utilities, etc. • Within project boundary, determine whether turning radii at existing intersections along the delivery route need to be modified • Assess whether surface replacements or upgrades will be required
Wildlife Studies • Typically include: • Avian use surveys • Raptor nesting surveys • Habitat inventory • Threatened, endangered, sensitive species focused surveys if appropriate • Bat habitat inventory and/or risk analysis • State Natural Heritage database/USFWS T&E species inquiries • Plant and noxious weed surveys, if appropriate • Studies will vary geographically and by state
Wetland Studies • It often makes sense to start with reconnaissance level study, saving complete delineation until the layout is final • All project facilities must be cleared for wetlands • Public road improvements, especially public road culvert replacements, are often forgotten • Good communication between wetland staff and design engineers is critical • Data management is critical • Keep a change log
Cultural Resource Studies • Consult with State Historic Preservation Office (SHPO) • Define the Study Area for Archeology and for Historic Architecture • Define the Area of Potential Effects (in consultation with SHPO) as Project is more precisely defined • Archeology • Historical Architecture
Transmission Interconnection Studies • Feasibility Study – estimates cost of interconnection • System Reliability Impact Study – determines cost and equipment for maintaining reliability of existing system • Complete Facility Upgrade Study determines final cost of all interconnection and system upgrade equipment • Negotiate Interconnection Agreement with transmission utility
Other Important Studies • Noise • Shadow Flicker • Visual Assessment • Property Values • Conduct Phase 1 Environmental Site Assessment (ASTM AIA Standards) • Etc.
Permitting Phase -- Local • Local • At most proposed wind energy project sites, one or more local approvals will be required. • The issuing authority may be a local planning commission, zoning board, town, city or village council, county board of supervisors or commissioners, or a similar entity. • Although some state siting boards are authorized to override local objections, most must first demonstrate that the proposed project would be consistent with local ordinances and that there is no reasonable objection to the development of the project.
Permitting Phase -- Local • Local • Similar to the state regulatory process, the need for local approvals and the process for obtaining approvals vary throughout the country. • In some areas, the local approval process will be time-consuming and the project will be subject to close scrutiny. In contrast, some municipalities require only a building permit. • The development team should assess which local approvals will be required and consult with local counsel.
Permitting Phase -- State • State • Numerous state regulatory programs are likely to be triggered by a proposed wind energy project. While such programs often mirror, implement (through delegated authority), or complement similar federal laws, the state version is typically more stringent than its federal counterpart. • Little NEPA • State Siting Statutes • Endangered Species • Wetland Permits • Stream Crossing Permits • Use Authorizations for State Owned Aquatic Land • Historic Preservation • Stormwater • Agricultural Protection • DOT (Roadway) Permitting
Permitting Phase -- Federal • National Environmental Policy Act • Federal Wetland and Waterbody Laws • National Pollutant Discharge Elimination System (NPDES) permits for stormwater during construction and operation • Endangered Species Act and other Wildlife Protection Laws • National Historic Preservation Act • Federal Aviation Administration Clearances • Federal Land Use Authorizations • Federal Transmission Line Interconnections
Final Engineering Design – Outline • Establish Design Team including Professional Engineer / (Engineer of Record) • Develop Design Criteria • These should capture design requirements for permits and plans • Client should review • Preliminary (Draft) Design • Drawings • Technical Specifications • Calculations • Final Design • PE Sealed • Issued for Construction
Design Disciplines • Design Disciplines Capabilities - Civil • Site Civil • Site civil drawing is a base map which is topographic survey obtained from client, or TtEC commissions a survey to develop the base map • Usually perform a pre-design “constructability” walkdown of WTG locations and intended access road routes to consider site natural features and landowner impacts • Roadway design: layout / direction / cross section / radii • Perform stormwater drainage calculations: Size and locate new culverts and identify soil erosion controls (e.g., silt fencing, stone rip-rap, etc.) • Geotextile Use • Structural • Foundation Design • Bridge Improvements
Design Disciplines • Design Disciplines Capabilities • Geotechnical • May need to perform a geotechnical investigation, as a pre-design task, to obtain site specific information at WTG locations and some locations along access roads • Detailed geotechnical investigation report serves as a basis for access road and WTG foundation design • Field Investigations • Geotechnical Reports as design input
Design Disciplines • Design Disciplines Capabilities • Electrical • WTG collector system, • Substation(s) • Transmission Line
Final Engineering Design - PE • Design requires supervision by licensed civil, structural and electrical PEs (if applicable) • PEs typically need to be licensed in State where project is located
Preconstruction • Finalize Turbine and Long-Lead-Time Item Procurement • Identify and requisition long lead time purchased items, such as wind turbines and transformers • Approvals for the later plans and permits (Storm Water Pollution Prevention Plan (SWPPP), Spill Prevention, Containment and Countermeasure Plan (SPCCP) and State DOT and US Army Corps wetlands permits) • Final Construction Plans and Drawings • Secure Construction Contractor • Develop Environmental Construction Compliance Plan • Develop Mobilization Plan
Construction • Mobilization – Make sure you have obtained the right pre-construction permissions: • Construction Trailers • Initial Laydown Areas • Sediment and Erosion Control • Safety and Environmental Training • Send out construction start notifications as required in permits
Construction • After the Notice to Proceed -- • Clearing and Grading • Access Roads and Public Road Improvements • Foundations • Electrical Collection System • Transmission Line • Substation and Interconnection Facilities • Tower and Turbine Erection • O&M Building/Visitor Kiosks • Commissioning • Mitigation Areas • Reclamation
Construction • Engineering support during construction • Provide home office support of construction activities following construction release of design drawings, to review contractor submittals and administer Field Change Requests (FCRs) and/or issue Design Change Notices (DCNs) • Provide field engineer, preferably from the design team, to assist with construction activities and ensure compliance with the design
Tetra Tech, Inc. • Tetra Tech, Inc. is a leading, U.S.-based national and international firm delivering solutions in, consulting, construction, engineering, remediation and restoration • Publicly traded company (TTEK) • Chosen by Smart Money magazine as one of the “10 Stocks for the Next 10 Years” • Annual revenues in excess of $1.4 billion; financial strength to stand behind large wind energy projects, including EPC & BOP • Over 8,500 employees in 250 offices world-wide • Consistently ranked in Engineering News Record as one of the top ten
Tetra Tech, Inc. • Acquisition of The Delaney Group – a well-respected leader in renewable energy construction • Experienced energy staff in all disciplines • More than 6 million hours without a lost work day over past two years • Injury rate is ¼ the national average • 70+ National Safety Council awards • Employee health and safety perception rating in top 2% nation-wide • ISO 14001 Certification for all services • First major full-service firm to earn certification with such broad coverage • ISO 9001 Certification for Wind Engineering • Documented quality procedures and systems to meet global standards and expectations
Recognized Expertise • Tetra Tech and Nixon Peabody chosen to write American Wind Energy Association (AWEA) Wind Facility Siting Manual • Frequent speaker on energy topics at AWEA, World Wind Energy Association and other renewable energy industry events • Papers on environmental compliance during construction • Included in New York Energy Research and Development Authority (NYSERDA) Wind Energy Tool Kit • Published in North American Windpower Journal • Through our Energy Management Services Supporting Energy Programs at More Than 60 DoD Installations World-Wide
Contact • Anntonette Alberti, JD • 518-488-8588 • Anntonette.Alberti@tteci.com