1 / 52

The roadside

Learn strategies to reduce roadside crashes and manage hazards effectively. Discover the importance of clear zones and road design to enhance safety and prevent accidents. Explore cost-effective measures and practical solutions.

koh
Download Presentation

The roadside

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. The roadside Hossein Naraghi CE 590 Special Topics Safety March 2003 Time spent:12 hrs

  2. The roadside • The forgiving roadside • Collision with roadside objects account for 25-30 percent of fatal crashes • Significant in both urban and rural environments • Measures to address this problem • Reducing crash frequency • Shoulder treatment • Speed control • Combating driver fatigue • Combating alcohol abuse

  3. The forgiving roadside (continued) • Reducing crash severities • Forgiving roadside • Develop cost-effective ways to reduce severity of run-off-road crashes • There are two strategies • Roadside clear zone • If a vehicle leaves the roadway, it is less likely to strike a roadside object • Impractical in many cases • Roadside hazard management program

  4. Roadside clear zones • Recovery area • The zone beside the road which let driver to be able to regain the control of the vehicle • If it has not struck a fixed object • If it has not rolled over • The distance vehicles travel along the roadside and the distance which it penetrates into the roadside

  5. Roadside clear zones (continued) • Depends on • Vehicle traveling speed • The angle vehicle leaves the roadway • Early studies in US established that with flat sides slopes • 80-85% of vehicles traveling at highway speeds could recover within 30 ft from the edge of the roadway • This distance was considerably greater • On curves • On steeper slopes

  6. Roadside clear zones (continued) • Clear zone • An area within the recovery area which is ideally kept free of roadside hazard • Roadside hazards • Poles, trees, and shrubs with trunks greater than 4 inches • Culvert end walls • Steep batters (greater than about 6:1 or ideally 4:1) • drains

  7. Roadside clear zones (continued) • Anything that pose a danger to errant vehicles • Any obstacles within the zone should either be removed or shielded with guard fencing • An area which reflects the the probability of crashes occurring on that road • The cost-effectiveness of providing such a zone

  8. Roadside clear zones (continued) • The clear zone dependent upon • Traffic speed • Roadside geometry • Traffic volume • It is a compromise between safety, economic and in many cases environmental consideration • If it is not practicable to provide width of clear zone, alternative remedial treatment such as guard fencing can be considered

  9. Roadside clear zones (continued) • The clear zone is measured from the edge of the traffic lane. • “For curves with radius of less than 600 m (2,000 ft), the clear zone width on the outside of the curve should be doubled” • In low speed environment of urban area, a clear zone of not less than 1 m wide may be accepted to achieve the balance between safety and aesthetic

  10. Roadside clear zones (continued) • Cross section • Flatter roadside slope have a significant effect on single vehicle crashes • Crash rates fall steadily as side slopes are flattened from 3:1 to 7:1 or flatter • Little crash reduction is expected by flattening from a 2:1 to 3:1 slope • Side slopes of 5:1 or flatter are needed (Zegeer and Council, 1992)

  11. Roadside clear zones (continued) • Clear zones and side slopes are closely related • Clear zone must include a flat traversable slope of 4:1 or flatter (Crillo 1993) • Slopes steeper than 4:1 are too steep to allow recovery of control • Vehicles encroaching on such slopes can be expected to travel all the way to the bottom if not rollover

  12. Roadside clear zones (continued) • Establishing and maintaining an obstacle free clear zone has definite safety benefits • It appears to be cost-effective on rural roads even at low traffic volumes • For volumes greater than 4000 vpd and speed around 62 mph a clear zone of 30 ft is required • Side slopes need to be flatter than 5:1 to significantly reduce the probability of rollovers

  13. Roadside hazard management • Where it is not possible to provide roadside clear zone • Impractical • Too expensive • Roadside hazards present some measure of risk to • Errant vehicles • Pedestrians at risk from such vehicles

  14. Roadside hazard management (continued) • The objective of roadside hazard management program is to keep this risk to a manageable level • With mass action programs, there is scope for a pro-active approach • It is required to identify the features associated with crashes of a given type, and then treat in priority order all sites which exhibit those features (Ogden and Howie 1990)

  15. Roadside hazard management (continued) • A hierarchy of treatments of fixed roadside hazards have proposed • Eliminate all obstacles from the roadside, either by good design and technology for new facilities, or removal or relocation of all existing obstacles • If it is not possible to eliminate all roadside objects • Identify those most likely to be struck, establish priorities, and organize removal or relocating

  16. Roadside hazard management (continued) • Make those objects most likely to be struck but impossible to remove harmless • Use a safety barrier or shield those obstacles impossible to remove or relocate • Typical treatments • Relocation of rigid utility poles, under grounding of cables, or replacement with frangible poles

  17. Roadside hazard management (continued) • Enhancing the safety of bridges and culverts by providing • Guard fencing • Bridge railing • Improved delineation • Flattening of batters or installation of guard fencing on steep or high embankments • Shielding the trees with guard fence or removing them from the clear zone • Removal of culvert headwalls or extension of culverts to increase recovery area

  18. Roadside hazard management (continued) • Replacing the old guard fencing which does not meet the current standards • Enhance delineation • Roadside devices • Pavement markings • The key component of any roadside management program is maintenance • Training of maintenance personnel is critical since proper installation and ongoing maintenance of many of these treatments is critical to their effectiveness

  19. Utility poles • Even though utility poles are present in a significant number of crashes involving fixed roadside objects, not every pole represents a hazard • In general the hazard increase with • Traffic flow • Pole density (poles per length of the road) • Offset from the edge of the road • Greater for poles outside the horizontal curves • Greater at sites with low pavement friction

  20. Utility poles (continued) • Treatment of hazardous poles • Relocation of the pole to a safer location • Locating light poles on the inside rather than outside of a horizontal curve • Shielding of poles with safety barriers • Guard fence • Impact attenuator • Use of slip base poles which break away at the base when impacted • Special electrical connections to ensure electrical safety

  21. Utility poles (continued) • Do not retard the impacting vehicle and may give rise to secondary crashes especially in area with high concentration of pedestrians or on narrow medians • Use of impact absorbing poles • Especially effective for area with high pedestrians activity • High friction pavements where the pole is on a curve • As a last and least satisfactory resort, attaching reflective delineators to the pole

  22. Trees • The most difficult aspect of roadside hazard management concerns tree • Trees can be helpful in shielding headlights and providing a visual barrier between the road and abutting property • Trees add to the aesthetic of the road • Trees can also form an important subliminal delineation function • Substantial trees close to roadway result in hazard

  23. Trees (continued) • Removing trees is highly effective • On hazardous location in rural areas • High volume traffic with high speed • Close to the roadway • On the outside of horizontal curve • Low pavement friction • Zegeer and Council (1992) quote a US study which suggest that • Clearing trees to provide an additional 3 ft of recovery space could reduce crashes by 22% • Additional 15 ft of recovery space reduce crashes by 71%

  24. Road signs • All road signs should have a frangible post unless located behind a safety barrier • Large signs such as advanced direction signs should be of a frangible design • When struck the supporting post shears and the vehicle passes beneath it • Installation of such posts is very important • Bolts must be correctly tensioned to ensure that they will shear • The base section must not be too low • Allowing debris to accumulate and impede break away • The base section also must not be too high • It can snag an impacting vehicle

  25. Road signs (continued) • Frangible designs are not suitable for use in low speed areas where vehicle does not have sufficient speed to satisfactory clear the falling pole • Roundabouts • Smaller, lighter signs mounted on lightweight posts are more appropriate for low speed areas • Lightweight posts made of light gauge steel pipe or channel section which easily deform on impact • applicable to smaller road signs such as warning signs, regulatory signs and chevrons

  26. Bridges and culverts • Hazards associates with bridges can be significant • Narrow bridges • increase the probability of vehicle colliding with bridge • Reduce the opportunity for safe recovery • Bridges are over-represented in crashes relative to their length of road system • Bridge crashes are more severe than crashes as a whole

  27. Bridges and culverts (continued) • Culverts can be hazard problem • Culvert end wall or pipe end often located quite close to the roadway • Culvert end wall can become less hazardous by being design to match the slop of embankment • Can be replaced with a grated inlet structure • Can be extended so the end wall is further from the roadway

  28. Bridges and culverts (continued) • Ogden and Howie (1990) produced guidelines for treatment of bridge sites based on bridge width, traffic flow, and bridge length • Install guideposts and reflective post-mounted delineators when street lighting not present • Install bridge width markers on or adjacent to bridge end post, piers, or abutments on both the left and right side of roadway

  29. Bridges and culverts (continued) • Provide edge lining with raised reflective pavement markers where bridge width marker installed to facilitate good lane control • When bridge is on or adjacent to a curve with radius of less than 2000 ft install chevron signs on the outside of the curve • Install the guard fencing according to current standards if warranted • Upgrade the installation of guard fencing with current standards for bridges with existed guardrail

  30. Other roadside hazards • Devices aim to protect pedestrians and bicycle facilities can potentially conflict with some of roadside safety principles • Where there are very large pedestrian flows solid bollards may be erected at curb line to protect pedestrians from errant vehicles • This is in conflict with forgiving roadside objectives • There is clearly a tradeoff between the safety of vulnerable road users and the safety of motorists

  31. Other roadside hazards • When the roadside object is necessary to protect vulnerable road users, those features should be as safe as possible • Horizontal rails which can spear an errant vehicle should be avoided • Vertical elements should be used • Less hazardous to motorists • More difficult for pedestrians to climb and walk on the roadway • Avoid to install hazardous features which have nothing to do with traffic • Features for Landscaping purposes

  32. Safety barriers • Safety barriers include • Guard fences • Flexible • Cable barriers • Rigid • Concrete barriers • Semi-rigid • Steel W-beam barriers • Box beam barriers • Crash cushions • Bridge barriers

  33. Safety barriers (continued) • Warrant and guidelines for the installation of guard fencing • On embankments • Slope and height exceed certain values • In US H/V of 3:1 and less and height of 5 m or more Figure 12.12 page 288 • Near roadside hazards • Any hazard within 30 ft of roadside may justify shielding

  34. Safety barriers (continued) • On narrow medians • To prevent head-on crashes • Where flow exceed 5000 vpd • Where road formation narrows • At some bridges and culverts • On the outside of sub-standard curves • Where differences between 85 percentile speeds and advisory speed is greater than 10 mph • To protect structures and pedestrians

  35. Steel guard railing • Steel guard railing • commonly of a rolled W-section • Rectangular hollow section • Acts by resolving kinetic energy possessed by an impacting vehicle into components in three dimensions • Vertical • Parallel to the rail • Perpendicular to the rail

  36. Steel guard railing (continued) • The perpendicular and vertical components must be reduced or dissipated to redirect the vehicle effectively • The energy dissipation is accomplished through bending and crushing of various parts of vehicle and guard rail installation, including the soil • In order to be effective guard railing must installed to allow the energy dissipation to occur

  37. Steel guard railing (continued) • The important point to stress is correct installation • The final product must be safer than an unprotected roadside object • Incorrect installation impose a greater hazard than the object it is shielding so the barrier can be ineffective or even counter-productive • Training program for people who make decision about guard rail program and people who install them is an important element of safety barrier program

  38. Existing barriers • Decision regarding acceptance, removal, modification or replacement of barrier based • Assessment of the performance of particular installation concerned • Significance of the departure from current practice • Other factors to consider in assessment • Potential hazard of the barrier in compare to hazard it shielded or compare that with a modern barrier

  39. Existing barriers (continued) • Suitability of barriers post-spacing, terminals and transitions • Barrier length, alignment, clearance and location relative to adjacent lane • Barrier height • Condition of the roadside between barrier and traffic lane • Alignment of the adjacent roadway

  40. Existing barriers (continued) • Examples of deficient guard rails • Guard rail too low • Vehicle may roll over the device • Guard rail too high • Vehicle may pass or trapped beneath the guard rail • Exposed, unanchored fish tail guard rail • Exposed end constitutes a hazard in itself • Result in the guard rail being demolished in a collision rather than decelerating and redirecting the vehicle

  41. Existing barriers (continued) • Guard rail with inadequate taper • Correctly tapered guard rail should have its end well away from the pavement • Guard rail with inadequate post spacing • On the approach to a bridge or rigid object • Post spacing should decrease near the bridge end post • Will stiffen the transition between guard rail and bridge • There is a need to inspect the existing guard rail and upgrading them to conform with requirements of current practice

  42. Concrete barriers • Concrete barriers • Commonly Known as New Jersey barrier • primarily used for median barriers on divided roads • Warrants are in place to provide directions for the use of this treatment • Represent a significant hazard to errant vehicles in all but very shallow angle collisions

  43. Concrete barriers (continued) • Advantages • Intend to prevent or minimize damage to vehicles during low-angle impacts • Does not defect to any appreciable degree, even under sever impacts • Negligible maintenance costs • Vehicles with low center of gravity are subject to roll over in collision with such a barrier • Modify section with a constant side slope may reduce the incidence of roll over

  44. Cable barriers • Cable barriers • Flexible barriers less common than rigid and semi-rigid barriers • Cost-effective • in low to moderate traffic flows • In situation where roadside or median design can accommodate the large deflection inherent in these types of barrier

  45. Median barriers • Median barriers • Warranted on situation of high flow and narrow median width • Effective in reducing head-on crashes on divided roads but may increase other kinds of crashes • A study of their installation in UK found • 15% reduction in fatalities • Little change in injury crashes • PDO crashes increased by 14%

  46. Bridge barriers • Bridge barriers • Design to prevent a light vehicle running of the edge of a bridge • Railings designed to retain heavy vehicles are heavier and more expensive • Warranted in exceptional situations with extreme crash consequences • Barriers on old bridges which do not meet the current standards may present a hazard • Old bridges with timber rails can lead to spearing crashes • Replacing or modification of the railing may be an appropriate treatment • Integrating the bridge railing and the approach guard railing to provide a continuous rail

  47. Crash cushions • Crash cushions • Design to absorb some of the kinetic energy of errant vehicle before it impacts the object • Are effective at the end of longitudinal safety barriers in • Medians and freeway gore areas • Bridge piers in narrow medians • End of concrete barrier wall • Toll plazas • Use readily available materials • Sand or water filled barrels

  48. Safety barriers and heavy vehicles • Heavier vehicle requires a stronger installation to restrain it • Higher center of gravity is more susceptible to rollover • Barriers for heavy trucks only justified at special locations • Encroachment of large truck could be catastrophic • Bridges adjacent to a school or apartment building • Near a petrochemical plant • Barriers to withstanding vehicles more than 9 ton are only warranted where traffic flow exceeds 100,000 vpd

  49. Shoulder treatment • Two major aspects of shoulders relate to • shoulder sealing • Pavement age drops • Paved shoulders are much safer than unpaved shoulders on rural roads • Reduce • run-off-the –road crashes • Head-on crashes • Chance of losing control due to loose material of unpaved shoulders • By providing a grater recovery and maneuvering space

  50. Shoulder treatment (continued) • A number of studies examined the safety benefit of paved shoulders • In an Australian study, Armour (1984), found that road with paved shoulders • 60-70 percent lower fatal crashes than road with unpaved shoulders • Benefit was greater on road section with curves or grades • Ogden (1993) in an study of Australian rural roads which had been treated with sealed shoulders as part of a maintenance program • With paved shoulder of 2-4 ft he found such a treatment lowered crash rate by 43% on vehicle km basis

More Related