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ENGR 340 Wind Energy & Transportation (Part II) Nadia Gkritza CCEE
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What is going to happen if you followed a truck moving a wind turbine component up to a hill?
How long will it take you to pass a truck carrying a wind turbine blade?
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Vehicle Performance Why vehicle performance important?
Determines all highway design and traffic operations Defines how transportation engineers must react to advancing vehicle technologies The single most important factor in defining the tradeoff between mobility (speed) and safety
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Forces acting on a road vehicle
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Power required to overcome air resistance
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What would you guess the drag coefficient of an Audi S4?
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What would you guess the drag coefficient of a 2005 Hummer H2?
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What would you guess the drag coefficient of a 2007 Honda Insight?
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Tire deformation (90%) Pavement penetration (4%)
Sources: Tire deformation (90%) Pavement penetration (4%) Friction, other sources (6%) Coefficient of rolling resistance: frl = coefficient of rolling resistance and is unit less, and V = vehicle speed in ft/s (m/s).
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Example Problem
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Solution
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Figure . Performance Curves for Standard Trucks (200 lb/hp) Source: Highway Capacity Manual Copyright, National Academy of Sciences, Washington, D.C. Reproduced with permission of Transportation Research Board
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Speed differential When a grade is longer than its critical length, it will cause the speed reduction for heavy vehicle by at least 10 mi/h. For example, the speed of a truck entering a grade of 5 percent at 55 mi/h will decrease by about 43 mi/h for a grade length of 1,000 ft and to about 27 mi/h for a grade length of 6,000 ft.
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Stopping sight distance
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1. Source: Highway Engineering, Paul H. Wright/ Karen K. Dixon, 2004
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What would you guess the perception/reaction time of a typical racer?
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Example Problem Two drivers each have a reaction time of 2.5 seconds. One is obeying a 55-mi/h speed limit, and the other is traveling illegally at 70 mi/h. How mush distance will each of the drivers cover while perceiving/reacting to the need to stop, and what will the total stopping distance be for each driver (using practical stopping distance and assuming G=-2.5%)?
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Solution
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Passing Sight Distance
Two-lane highways. The passing vehicle should be able to see sufficient distance ahead, upcoming traffic to complete the passing maneuver without cutting off the passed vehicle before meeting the opposing vehicles. Actually, it is harder to passing a long vehicle which exceed 150 feet. Source: A Policy on Geometric Design of Highway and Streets, AASHTO, 2004
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Table PSD values determined by Harwood and Glennon for specific passing scenarios
Source: NCHRP Report 605, Passing Sight Distance Criteria, 2008, Douglas W. Harwood, David K. Gilmore, Karen R. Richard, Joanna M. Dunn, Carlos Sun
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Elements of passing sight distance for two-lane highways Source: A Policy on Geometric Design of Highway and Streets, AASHTO, 2004
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Highway Design Standards
Design Traffic Volume: road should be designed for an acceptable level of service (LOS) and a specific traffic volume. LOS A LOS B Source: A Policy on Geometric Design of Highway and Streets, AASHTO, 2004
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LOS C LOS D LOS E LOS F
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Capacity Analysis Base Conditions for LOS lane widths,
lateral clearances, access frequency (non access controlled highways), terrain; traffic stream conditions such as the effects of heavy vehicles (large trucks, buses and RVs), and driver population characteristics. Density: measure of LOS k=q/u Where q = flow in veh/h, u = speed in mi/h (km/h) and, k = density in veh/mi (veh/km).
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Design Speed Selected speed used to determine the various design features of the roadway. Type of Roadway Terrain Rural Urban US (mi/h) Metric (km/h) Freeway Level 70 110 50 min 80 min Rolling Mountainous 50–60 80–100 Arterial 60–75 100–120 30–60 50–100 40–50 60–80 Collector 40–60 60–100 30+ 50+ 30–50 50–80 20–40 Local 20–30 Source: A Policy on Geometric Design of Highways and Streets, AASHTO,2004.
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Analysis Flow Rate Where:
vp = 15-min passenger-car equivalent flow rate (pc/h/ln), V = hourly volume (veh/h), PHF = peak-hour factor, N = number of lanes, fHV = heavy-vehicle adjustment factor, and fp = driver population factor.
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Peak-Hour Factor Where: PHF = peak-hour factor,
V = hourly volume for hour of analysis, V15= maximum 15-min flow rate within peak hour 4 = number of 15-min periods per hour
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Passenger Car Equivalents (PCEs) for Extended Freeway Segments
Heavy Vehicle Adjustment Large trucks, buses and recreational vehicles have performance characteristics (slow acceleration and inferior braking) and dimensions (length, height, and width) that have an adverse effect on roadway capacity. The adjustment factor fHV is used to translate the traffic stream from base to prevailing conditions. Passenger Car Equivalents (PCEs) for Extended Freeway Segments Factor Type of Terrain Level Rolling Mountainous ET (trucks and buses) 1.5 2.5 4.5 ER (RVs) 1.2 2.0 4.0
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Example A four-lane urban freeway is located on a rolling terrain. The directional peak-hour volume is 3,800 vehicles with 2% large trucks and 4% buses. No recreational vehicles are present. Calculate fHV. Solution: Now assume that a bus strike will eliminate all bus traffic… but it is estimated that for each bus removed from the roadway, six additional cars will be added as travelers seek other means for travel. Calculate fHV.
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Example (cont’d) Number of trucks (before): 76
Number of buses (before): 152 Number of passenger cars (before): 3,572 Number of trucks (after): 76 Number of buses (after): 0 Number of passenger cars (after): 3, *6=4484 New volume: 4,560 PT=76/4560=0.017 or 1.7%
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Safety Issues Vehicle Type Total Percent Passenger Cars 18,350 40.4%
Light Trucks 17,902 39.4% Large Trucks 3,215 7.1% Motorcycles 4,595 10.1% Buses 221 0.5% Other/Unknown 1,152 2.5% 45,435 100.0% Table Vehicles Involved in Fatal Crashes by Vehicle Type - State : USA, Year : 2009 Source: NHTSA-Fars
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Fatalities by Vehicle Type
Year Occupants by Vehicle Type Passenger Cars Light Trucks Large Trucks 2000 20,699 11,526 754 2001 20,320 11,723 708 2002 20,569 12,274 689 2003 19,725 12,546 726 2004 19,192 12,674 766 2005 18,512 13,037 804 2006 17,925 12,761 805 2007 16,614 12,458 2008 14,646 10,816 682 2009 13,095 10,287 503 Table Persons Killed, by Person Type and Vehicle Type, State : USA Source: Source: NHTSA-Fars
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Crash Rates Year Vehicle Type Passenger Cars Light Trucks Large Trucks Involvement Rate per 100 Million VMT Involvement Rate per 100,000 Registered Vehicles 2000 1.76 21.76 2.17 26.91 2.43 62.26 2001 1.73 21.41 2.13 26.42 2.31 61.38 2002 1.7 21.03 2.14 26.49 57.86 2003 1.65 20.19 26.18 60.86 2004 1.58 19.27 2.05 25.00 2.22 59.99 2005 1.56 18.62 2.02 24.19 58.37 2006 1.5 17.72 1.93 22.82 54.04 2007 1.42 16.57 1.85 21.63 2.04 51.32 2008 1.3 14.73 1.67 19.01 1.8 45.4 Table Vehicles Involved in Fatal Crashes, State : USA Source: Source: NHTSA-Fars
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Rail Transportation for Wind Industry
Wind Belt Transportation Improvement Project (TIGER) Reduce transportation costs by 57 % compared to truck, for every wind turbine shipped by rail; Enable to compete with imported wind, provide long-term U.S. manufacturing jobs and stimulate local economies; Reduce emissions costs by 73% and carbon dioxide emissions by 82 % compared to truck, for every wind turbine shipped by rail; Increase highway safety by 58 % compared to truck, for every wind turbine shipped by rail; Reduce highway maintenance costs by 68 % compared to truck; Nearly double the capacity of a primary rail line that serves the states of Iowa, Missouri, and Minnesota Source: Wind belt transportation improvement project, TIGER discretionary grant application.
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Estimated Per-Mile Transportation and Public Cost Comparison for a Complete Wind Turbine, Rail Compared to Truck Source: Wind belt transportation improvement project, TIGER discretionary grant application.
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The Union Pacific Railroad Spine Line lies in the center of the Midwest Wind Belt, enabling rail transportation of wind turbine components to be economically and efficiently distributed throughout the Wind Belt. Source: Wind belt transportation improvement project, TIGER discretionary grant application.
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Short Video about 37 Degree Turning Radius for Blade Truck
Other videos:
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