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Welcome to the International Right of Way Association’s. Course 901 Engineering Plan Development and Application. Introductions. Who you are. . . What you do . . . Where you work . . . How long. Objectives. Identify and Use Plan Information. Understand Engineering Terms.
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Welcome to the International Right of Way Association’s Course 901 Engineering PlanDevelopment and Application
Introductions Who you are. . . What you do . . . Where you work . . . How long . . .
Objectives • Identify and Use Plan Information • Understand Engineering Terms • Explain Plans • Use Engineering Tools • Apply Principles to Your Work
Schedule • Follow Participant’s Manual 8:00 – 8:30 Introductions, etc. 8:30 – 2:45 Use of Engineering Plans and Plan Development 2:45 – 3:45 Other Plans and Maps 3:45 – 4:15 Summary and Review 4:15 – 5:00 Exam
Graphic Language ➢ Lines ➢ Graphs ➢ Charts ➢ Symbols Engineering Plans
Right of Way Plans used by: • Appraiser • Negotiator • Attorney • Engineer/Surveyor • Value Property • Explain detailsAcquire Property • Present in Court • Legal Documents • Design & Construct
Three View Concept Top View Side View End View Plan View Profile View Cross Section Length and Width Height and Length Width and Height Each View is Perpendicular to Others Gives 3 Dimensional Picture Of Project
Plan View (Top View) • Existing Features - Dashed Line • Proposed Construction - Solid Line
Plan View (Top View) • Property Information • Drawn to Scale
Engineers Scale Inches divided into multiples of 10 per inch
Architects Scale Divides feet into inches and fractions
North Arrow - Orientation of Plan Three Norths - Geographic True North - Magnetic North - Datum North
Centerline - Control Line ➢ Horizontal Direction of Project ➢ Deflection Angle Changes - Delta ()
Compass Bearings • Four Cardinal (Main) Directions • ➢ “N” , “E”, “S”, & “W” • Quadrants (90°) • ➢ “NE” , “SE”, “SW”, & “NW”
Compass Bearings Shows Direction of Centerline or Property line
Stations • Marked in 100’, 100 m or 1000 m Intervals • Always Numbered Positive • Used for Reference and Location • Intermediate Points Called “+” (Plus) • Directions: “BK”, “AH”, “LT”, “RT”
Exercise #1 - Utility Centerline 3962 +2126 N = 58°-30’ Sta 60+88 6088 2126’ PI Sta 39+62 N81°-45’E 60+88 81°-45’ -23°-15’ 1962’ 58° -30’ N23°-15’E = 58°-30’, Rt 20+00 =2000 +1962 3962 39+62 POB, Sta 20+00 Scale: 1” = 500’
Station Equations/Equalities • Used When Stations Not Continuous • Point has Two or More Station Numbers • ➢ One Back and One Ahead • Calculating Correct Distance Between Stations • ➢ Add Individual Segment Lengths
Station Equations R/W NEW HIGHWAY C L R/W
Highway & Railway Curves PI T T T - Tangent - Straight Section of Centerline PI - Point of Intersection - Delta Angle - Deflection Angle
Simple Curve PC - Point of Curvature PI D PT PC PT - Point of Tangency L POC L - Length of Curve POT R - Radius R POC - Point on Curve D POT - Point on Tangent
Reverse Curve Two Curves, Adjacent, Opposite Directions PRC PRC - Point of Reverse Curvature Has 2 PIs
Compound Curve Two Curves, Adjacent, Same Direction PCC Different Radii PCC - Point of Compound Curvature
Spiral Curve Constantly Changing Radius Spiral on Each End of a Simple Curve TS - Tangent to Spiral SC - Spiral to Curve CS - Curve to Spiral ST - Spiral to Tangent
Degree of Curvature • Measured 100’ Along Centerline • Angle at center of arc 100’ D
Degree of Curvature-D • Indicates Flatness/Sharpness of Curve • ➢ Small D - Large Radius • ➢ Large D - Small Radius • Examples: • ➢ 1° Curve Radius = 5,729.58’ • ➢ 10° Curve Radius = 572.96’
Exercise #2 – Highway Centerline PI: 3962 -T = - 802 PI: 3962 (1463’) PC = 3160 + T = +802 Sta 31+60 PT = 4764 47+64 Sta 47+64 46+23 PC: 3160 + L = +1463 PT: 4623 31+60 Sta 46+23
Offsets • PerpendicularDistance Right or Left • of Centerline ➢ Locate any Point off Centerline ➢ Use Radial Line on Curve 65’ Lt, Sta 14+50 P L (155’) 14+00 21+00 (650’) 90’ Rt, Sta 21+00 6502+ 1552= LENGTH = 668.2’
Contours • Lines of Equal Elevation • Shows Shape and Slope of Land • Interval - Elevation Difference • Between Contour Lines
Contours • Relative Spacing of Lines Indicates Slope • ➢ Close Lines = Steep Slope • Contours Point Upstream
Exercise #3 - Contours 50’ • 1. Map Scale? 1” = • 2. Contour Interval: • 3. Sidewalk Width: • 4. Elevation Difference: • 5. Ball Rolls: • 6. In Flood Plain: • 7. Elevation: • Equation: Saratoga = Bridge St • 9. Saratoga St. R/W: • 10: Bridge St. R/W: 1’ 8’ 1.2’ South 238 & 240 863 9+9 5 0+00 60’ 60’
State Plane Coordinate System • Survey Control - Latitude & Longitude Converted to Coordinates • Establishes Precise Location • Four Datums: • ➢ Two Horizontal – NAD 27 & NAD 83 • ➢ Two Vertical – NGVD 29 & NAVD 88 • Zones - Depends on Size & Shape of State
State Plane Coordinate System • Point Identified by Two Coordinates ➢ “X” is “Easting” ➢ “Y” is “Northing” • Vertical Control Surveys Establish Elevations • Advantages: ➢ Excellent Control over Large Areas ➢ Accurate Locations
Exercise #4 – State Plane Coords 1. PI Curve GV-2: a. Station __________ Offset _______ b. N ____________ E ___________ 21+89.46 7’ Lt 10,152.824 5,473.141 2. Drill Hole B1: a. Station __________ Offset _______ b. N ____________ E ___________ 24+53 5’ Lt 10,210 5,733 3. Telephone Pole “TEL-25”: a. Station __________ Offset _______ b. N ____________ E ___________ 21+53 44’ Lt 10,177 5,428
Exercise #4 – State Plane Coords 4. PL Intersection with R/W line: a. Station __________ Offset _______ b. N ____________ E ___________ 21+53 47’ Rt 10,089 5,453 5. BM “A-267”: a. Station __________ Offset _______ b. N ____________ E ___________ 28’ Lt 24+86 10,240 5,761
Profile View • Side View – (Length & Height) • Stations & Elevations on Centerline Only ➢ Existing – Dashed Line ➢ Proposed – Solid Line
Profile View • Horizontal Scale same as Plan View • Vertical Scale exaggerated for Clarity • Datum - Reference Elevation • Bench Marks - Known Location & Elevation
Profile Grade Line/Point • Profile Grade Line - Stations & Final Elevations on Centerline • Profile Grade Point - Centerline Elevation at Specific Station
Profile Grade Line • Percent Grade - Rise (+) or Fall (-) • ➢ % = 100 V/H V = Change in Elevation H = Horizontal Distance in Feet
Vertical Highway Curve • Parabolic Curves ➢ Sag or Crest
Vertical Highway Curve • PVC - Point of Vertical Curve • PVI - Point of Vertical Intersection • PVT - Point of Vertical Tangent • Length = PVT - PVC
Highway Plan – Profile Sheet • ➢ Provides Two Dimensional View
Exercise #5 – Vertical Curves 1. Percent Grade: 2. 600’ Curve: PVC: ______ PVT: _______ 3. 400’ Curve: PVC: ______ PVT: ______ 4. Cut or Fill @: 11+00: _____ 25+00:______ 5. Datum:_________________ 100(19.5)/(650)= - 3.0% 12+50 18+50 20+00 24+00 12’ F 4’ C Mean Sea Level
Utility Typical Cross-Section Overhead Line (H frame)Typical Section
Highway Cross-Section • Shows Construction Details • Perpendicular to Centerline