Evaluation of Zero-Length Vertical Curves

To evaluate the use of zero-length vertical curves with respect to Texas Department of Transportation design practice, construction results, and vehicle dynamics, and to compare zero-length vertical curves with minimum-length design vertical curves, 20 zero-length vertical curves and 15 minimum-leng...

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Veröffentlicht in:	Transportation research record 1999, Vol.1658 (1), p.52-59
Hauptverfasser:	Wooldridge, Mark D., Nowlin, R. Lewis, Parham, Angelia H.
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Buildings. Public works Exact sciences and technology Ground, air and sea transportation, marine construction Road construction. Pavements. Maintenance Road transportation and traffic Road types (roads, freeways, express ways, etc.) Transportation infrastructure
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container_title	Transportation research record
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creator	Wooldridge, Mark D. Nowlin, R. Lewis Parham, Angelia H.
description	To evaluate the use of zero-length vertical curves with respect to Texas Department of Transportation design practice, construction results, and vehicle dynamics, and to compare zero-length vertical curves with minimum-length design vertical curves, 20 zero-length vertical curves and 15 minimum-length vertical curves were evaluated. Evaluations performed included examinations of sight distance for zero-length vertical curves, surveying roadway profiles, and measuring vertical accelerations. Sight distance criteria were found to be generally inapplicable below 2 percent for sag vertical curves. For crest vertical curves, sight distance criteria were inapplicable below 1 percent for design speeds of 90 km/h or less and inapplicable below 0.5 percent for design speeds of 100 to 120 km/h. The results of vertical acceleration testing showed that, below 0.5 percent grade change, no practical difference was found between zero-length and minimum-design-length vertical curves. Between 1.0 and 0.5 percent grade change, significantly higher accelerations were measured for high-speed tests on zero-length vertical curves. Finally, it was found that zero-length vertical curves were more likely to meet drainage grade requirements than minimum-design-length vertical curves were.
doi_str_mv	10.3141/1658-07
format	Article
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subjects	Applied sciences Buildings. Public works Exact sciences and technology Ground, air and sea transportation, marine construction Road construction. Pavements. Maintenance Road transportation and traffic Road types (roads, freeways, express ways, etc.) Transportation infrastructure
title	Evaluation of Zero-Length Vertical Curves
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