Geometric & Pavement Design - examples.ppt

Editor's Notes

• #2: Find K values for the crest and sag vertical curve. Ksag = 96 for 50 mph Kcrest = 84 for 50 mph Because the combination sag & crest curve goes between two flat grades: G1 for the sag = 0 G2 for the sag = G1 for the crest G2 for the crest = 0 Therefore, A for the crest = A for the sag Use L = LA to express length in terms of K. We know that A is the same for both because A = G2 – G1 and Lsag = 96A Lcrest = 84A Use a vertical relationship to get the second equation: AL/200 = Yf = AL/200 Therefore, ALsag/200 + ALcrest/200 = 24 ft Substitute and solve for A A(96A)/200 + A(84A)/200 = 24 A = 5.16% = G2 for the sag = G1 for the crest Find curve lengths Lsag = KsagA = (96)(5.16) = 495.36 ft. Lcrest = KcrestA = (84)(5.16) = 433.44 ft Find total length of highway that must be reconstructed Need one sag and one crest curve on each end = 2(495.36) + 2(433.44) = 1857.6 ft Add the 200 ft long flat section at the top = 1857.6 + 200 = 2057.6 ft.
• #4: The proper equation is equation 3.33 tan(α) + fs = (V2/gRv)(1 – fstan(α)) Although In the typical formula the fstan(α) term is ignored because it is small, this is the normal component of the centripetal acceleration and will not be ignored here. Solve for α tan(α) + 0.20 = ((100 x 1.47)2/(32.2)(1000))(1 – 0.20tan(α) tan(α) + 0.20 = 0.671(1 – 0.20tan(α) tan(α) + 0.20 = 0.671 – 0.1342tan(α) 1.1342 tan(α) = 0.471 tan(α) = 0.4153 α = 22.55° e = 41.53 If we ignored the normal component of centripetal acceleration, e = 47.11 As we get into big superelevations then it is no longer practical to ignore the normal component Degree of curvature (π/180)RΔ = 100Δ/D D = 5.73 Curve length L = 100Δ/D = 523.56 ft Stationing T = Rtan(Δ/2) = 267.95 ft PC = PI - T = 112510 – 267.95 = 1122+42.05 PT = PC + L PT = 112510 + 523.56 = 1130+33.56
• #6: Determine if horizontal curve is adequate for 40 mph R = 180L/πΔ = 553.9 ft (this is the centerline radius) Rv = centerline radius – 5 ft = 548.9 ft Rv = V2/(g(fs + e)) Use limiting value of fs from Table 3.5 = 0.150 V = 60.9 ft/s = 41.44 mph OK Determine adequacy of vertical curve K = L/A = 580/(3 - -2.5) = 105.5 From Table 3.2, K = 44 for 40 mph OK What is the available SSD? Horizontal curve: SSD = (πRv/90)(cos-1((Rv – Ms)/Rv)) SSD = (19.16)cos-1(0.9453) SSD = 364.6 ft This SSD consists of braking distance + reaction time (2.5 x initial speed) Vertical curve (assume SSD < L): SSD2 = 2158L/A = 2158(580)/5.5 = 227,571 SSD = 477 ft Therefore, horizontal is more limiting and SSDavailable = 364.6 ft On packed snow and ice the braking distance will be much greater due to reduced friction S (braking distance ignoring aerodynamic resistance) = γb(V2)/(2g(ηbμ + frl +/- sinθ) Assumptions Mass factor = 1.04 Braking efficiency = 0.80 (can’t really assume ABS at this juncture) Coefficient of road adhesion from Table 2.4 = 0.10 Grade = assume 0, since part will be uphill and part will be downhill S = (1.04)(V2)/(2(32.2)((0.80)(0.10)+0.01(1+V/294) + 0)) S = 0.0161V2/(0.08 + 0.01 + V/29400) S = 0.0161V2/(0.09 + V/29400) Calculate stopping sight distance SSD = reaction time + braking distance SSD = 2.5(V) + 0.0161V2/(0.09 + V/29400) = 364.6 32.81 + 0.0124V = 0.225V + 0.000085V2 + 0.0161V2 0 = 0.01619V2 + 0.2126V – 32.81 V = 38.93 or -52.06 V = 38.93 ft/s = 26.48 mph Check SSD SSD = 2.5(38.93) + (1.04)(38.932)/(2(32.2)((0.80)(0.10)+0.01(1+38.93/294) + 0)) SSD = 97.3 + 268.0 = 365.3 ft OK Recommended speed limit could be posted at 25 mph or even 20 mph
• #11: Convert each type of bus to an ESAL (use 4th power law as approximation) Articulated = 0.4823 + 1.1158 + 0.1667 = 1.7647 Regular = 0.211 + 1.52 = 1.7352 Calculate total ESALs per day 1.7647(40) + 1.7352(80) = 209 ESALs/day Calculate total lifetime ESAL loading ESALs per day during the school year is probably much higher than not during Assuming ESAL loading is about half during the summer and during weekends Assume summer = 3 months = 100 days Assume school year = 265 days (of which about 80 are weekends/holidays) ESALs = (185)(209) + (80 + 100)(209/2) = 57,475/year Grow the ESALs over 40 years from present year Total ESALs = (57,475)((1 + 0.02)40 – 1)/0.02 = 57,475(60.40) = 3,471,604 ESALs Use WSDOT Table to determine PCC design Need to select a reliability (might want to use a high one since it is a highly visible road) If reliability = 75% then design is 9” PCC over 4” or 6” of base course If reliability = 85% then design is 9.5” PCC over 4” or 6” of base course If reliability = 95% then design is 10.5” PCC over 4” or 6” of base course
• #12: Grow the ESALs over 40 years from present year Total ESALs = (57,475)((1 + 0.02)40 – 1)/0.02 = 57,475(60.40) = 3,471,604 ESALs Use WSDOT Table to determine flexible design Need to select a reliability (might want to use a high one since it is a highly visible road) If reliability = 75% then design is 8” HMA over 4” of base course If reliability = 85% then design is 8.5” HMA over 4” of base course If reliability = 95% then design is 10.0” HMA over 4” of base course Keep in mind the WSDOT assumptions in the table Note that pavement depths of HMA and PCC are quite similar Mention that ESALs for rigid and flexible pavement are not the same but it is okay for the broad assumptions of this example