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Intersection Safety

Intersection Safety. Hossein Naraghi CE 590 Special Topics Safety March 2003. Time Spent: 13 hrs. Intersection Safety. Intersections are the most critical element of the road network At grade intersections are risky

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Intersection Safety

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  1. Intersection Safety Hossein Naraghi CE 590 Special Topics Safety March 2003 Time Spent:13 hrs

  2. Intersection Safety • Intersections are the most critical element of the road network • At grade intersections are risky • Because different road users (vehicles, pedestrians, cyclists) are required to use the same space • Collision is only avoided if they are separated in time • In US over one-half of reported urban crashes and over one-third of reported rural crashes are at intersections • In Australia 43% of urban crashes and 11% of rural crashes are at intersections

  3. Intersection Safety (continued) • The main factors affecting safety at intersections • Number of legs • Angle of intersection • Sight distance • Alignment • Auxiliary lanes • Channelization • friction • Turning radii • Lighting • Lane and shoulder widths • Right of way (rules, signs, signals) • Approach speed • Driveways

  4. Intersection Safety (continued) • In general as traffic flows and the ratio of minor to major road flow increases, more control is necessary for both safety and capacity reasons • A British guideline on appropriate intersection treatments classified by approach traffic volumes for both major and minor road flow is shown in Figure 9.1 (page 185)

  5. Intersection Safety (continued) • In increasing degree of standard and control, intersections are • Uncontrolled • Relying on a priority rule to indicate right of way • Priority road • Designated by Yield or Stop signs • Roundabout • Signal controlled • Turning traffic filtering through on-coming traffic • Control of some or all turning movements • Grade separation

  6. Intersection Type • Table 9.1 shows how crash rates varies with the type of intersection and degree of control • Things that influence the safety performance • Different configurations • Cross intersections • T-intersections • Different forms of control • Signals • Roundabouts • Different road functions • Major arterials • Minor arterials • Collectors • Local streets

  7. Intersection Type (continued) • From the data in Table 9.1 • It can be seen following intersection configurations tends to be safer than others • Roundabouts • T-intersections • Table 9.2 shows the appropriate intersection type in relation to the role of the intersecting roads in a road functional hierarchy

  8. Uncontrolled Intersections • An uncontrolled intersection • The most basic form of intersection • Relying on regulatory rule to resolve priority between conflicting users • Only applicable in very low volume situations • Requires establishment and maintenance of a sight triangle • Enables vehicles on conflicting paths to see each other

  9. Priority Controlled Intersections • Intersections of one major road with one or more minor roads • Traffic on minor roads controlled with stop or yield signs • The decision to whether install stop or yield sign is based primarily on sight distance consideration • In US a yield sign is used where sight distances permit traffic on the controlled street to approach safely at 10-15 mph or higher, otherwise a stop sign is used

  10. Priority Controlled Intersections (continued) • Priority controlled intersections • Are effective at low volume sites with low approach speeds • Should not over-utilized as this will likely lead to disrespect • Rural Intersections • Most intersections in rural areas are likely to be priority intersections • One particular treatment is the conversion of a cross intersection to a pair of staggered t-intersections

  11. Rural Intersections (continued) • Staggered t-intersections • Are very effective in reducing both crash frequency and crash severity • Sweden reported that paired t-intersections are 1.5-2 times as safe as cross intersections for the same traffic flow • US studies found that injury consequences is 1.5 times greater at cross intersections • It is preferable to orient the stagger such that the drivers cross the nearest traffic lane at nearly a right angle and then have unimpeded exit from the far lane

  12. Rural Intersections (continued) • For traffic driving on right, a left-right stagger is provided with a protected right turning area in the center of the major road • Figure 9.4a and 9.4b show the staggered t-intersections for the traffic driving on the left and on the right respectively

  13. Roundabouts • A roundabout is a traffic control device involving a one-way circulating roadway around a central island • Priority within roundabout is controlled by yield signs, although occasionally signal control may be used • Roundabouts are rare in US in compare to UK, principally because of the use of an onside rather than an offside priority rule (Todd, 1988, 1991)

  14. Roundabouts (continued) • From an operational viewpoint, roundabouts may be applicable: • At intersections where traffic volumes lead to unacceptable delays to traffic on minor road with stop, yield control or traffic signals • At intersections with high left turning volumes • At intersections with more than four approaches • Priority control may not resolve the situation • Signals may be less efficient due to the large number of phases

  15. Roundabouts (continued) • At intersections between collectors or between a collector and a local street • Where disproportionally high number of crashes occur • On local streets • To control speeds • At rural cross intersections • Where there is a crash problem involving vehicles on adjacent approaches or turning vehicles • At intersections where a main road passes through a rural town

  16. Roundabouts (continued) • Where minor roads intersect at ‘Y’ or ‘t’ intersections • These involve high proportion of turning vehicles • Roundabouts are less likely to be suitable where: • A satisfactory geometric design can not be provided • Restriction of space or topography • Traffic flows are unbalanced

  17. Roundabouts (continued) • High volumes on one or more approaches which would dominate use of the roundabout • Major road intersect a minor road • Roundabout would cause unacceptable delay to the minor road traffic • Considerable pedestrian activities • High vehicle speed or heavy flows would make it difficult for pedestrians to cross (unless pedestrian crossing facilities are provided) • At an isolated intersection in a network of linked signals

  18. Roundabouts (continued) • It is preferable to provide a signalized intersection and incorporate it to the linked system to minimize delay, energy consumption and emissions • Peak period reversible lanes are used • Traffic flow leaving the intersection interrupted by a traffic control device • e.g. a pedestrian crossing could result in traffic queues blocking the intersection

  19. Roundabouts (continued) • Good safety record results from • Smaller number and spatial separation of conflict points • Control on approach speeds • Low relative speeds at conflict points • Simplicity of decision making for drivers • Good safety record can be enhanced by:

  20. Roundabouts (continued) • Provision of splitter islands on approaches • Provides additional advance warning to driver • Give a good visual cue of the location of the intersecting traffic flows • Providing refuges for pedestrians • Allow them to cross the road in stages • Safety problems can occur if: • The merging angle is too sharp • The roundabout is of unusual shape

  21. Roundabouts (continued) • Signing is inadequate or confusing • There are steep approach gradients • There is adverse crossfall on the circulating roadway • There are slow-moving vehicles • Bicyclists • The deflection on approach is insufficient to slow vehicles to a safe speeds • For safety, roundabouts with heavily flared entries should have as much entry path deflection as possible

  22. Roundabouts (continued) • Pedestrians and bicyclists safety at roundabouts • The major safety problem at roundabouts is with bicyclists and to lesser extent with pedestrians • A British study found that 22% of crashes at roundabout involved a bicyclist, compared with only 8% of crashes at signalized intersections • Another study found that crash rates involving bicyclists at roundabouts in the UK were up to 15 times greater than that of cars at roundabouts

  23. Roundabouts (continued) • The problem is one of a bicyclist circulating within roundabout being struck by an entering vehicle (i.e. failing to give way) • Concern about the increased risk to cyclists needs to be seriously considered when weighing the benefits and disbenefits of adopting a roundabout treatment at a particular location • In some cases, bicyclists safety has improved following the replacement of a signal-controlled intersection by a roundabout, this was attributed to lower vehicle speeds

  24. Roundabouts (continued) • Measures to improve bicyclist safety at roundabouts • Avoid squeeze points on the approach • Ensure adequate deflection and speed control • Speed should not exceed 30 mph • Avoid large roundabouts • Discourage high speed circulating traffic • Avoid excessive width of the circulating roadway • Ensure sight lines are not obstructed • Consider provision of paths and ramps • to allow bicyclists and pedestrians to bypass the roundabout by moving from island to island • Provide adequate lighting

  25. Roundabouts (continued) • Pedestrians at roundabouts • Pedestrians are as safe at roundabouts as at other intersections by consideration of following factors • Provision of splitter islands • Allow pedestrians to cross the road in stages • Slower vehicle speeds • The facility required for pedestrians depend on the amount and intensity of their activities

  26. Roundabouts (continued) • It may be necessary to provide a signal-controlled pedestrian crossing adjacent to roundabout • It needs to be some distance away from the roundabout to ensure that the traffic does not queue back and block the circulating roadway • It may be necessary to provide a pedestrian fence to prevent pedestrians crossing the road away from the pedestrian crossing • Mutual visibility of pedestrians and motorists is important to maximize pedestrian safety, this can be enhance by:

  27. Roundabouts (continued) • Prohibiting parking on the approach to the roundabout • Providing a higher level of street lighting • Ensuring signs and vegetation do not obscure the view of pedestrians, particularly children • Safety-effectiveness and cost-effectiveness • Except for situations involving significant numbers of bicyclists, a number of studies have shown that roundabouts are highly cost-effective in safety terms as replacement for stop or yield controlled intersections • An Australian study found a 78% reduction in casualty crashes by installing roundabouts at low volume sites

  28. Roundabouts (continued) • Another study in UK found that the installation of mini-roundabouts at existing priority controlled intersections can reduce crashes by 30-40%, and at existing signalized intersections can reduce fatal and serious crashes by 40-60% • The cost-effectiveness of an Australian roundabout installation indicates a benefit to cost ratio of 7.5 for crash saving alone, over the project life of ten years

  29. Traffic Signals • By separating in time the use of road space across major traffic flows, traffic signals have the potential to significantly reduce conflicts • Effects of signalization • Under right circumstances, traffic signal installation will reduce the number and severity of crashes • It is not clear whether road safety benefits will result if the site has fewer than 3 casualty crashes per year prior to signalization

  30. Traffic Signals (continued) • If signals are installed where the site satisfies a safety warrant, some specific result can be quoted: • A UK study based on 34 intersections found that • Sites with more than 4.7 casualty crashes per year in the before period experiences a statistically significant reduction of 48% • Sites with fewer than 4.7 casualty crashes experienced non-significant increase of 5.3% • A US study in the state of Michigan, based on 102 intersections, found a 15.5% reduction in total crashes

  31. Traffic Signals (continued) • Controlled turns • Fully controlled left turn have a great safety benefits • Cameron and Foong 1991, examined 217 intersections approaches at which left turn phases had been installed • Installation of fully controlled left turn led to a statistically significant reduction in all casualty crashes 45% • Reduction of 82% in crashes involving vehicles turning from opposite direction • 48% reduction in right angle crashes • 35% reduction in pedestrian crashes • 72% increase in rear end casualty crashes

  32. Traffic Signals (continued) • The safety benefits of fully controlled turns which have been indicated in several studies are due to clear and unambiguous direction which they present to drivers • A study examined the effects of the left turn phase on intersection capacity • Full control of left turns yields poorer intersection performance than partial control under virtually all conditions • The difference in performance is slight and unlikely to disprove the safety advantages

  33. Traffic Signals (continued) • Advance warning • Advance warning are relevant where • A poor visibility of intersection • over a crest vertical curve • A high speed approach • The first signal after a long period of uninterrupted flow conditions • Rural highway enters a city • A study in US concerning active advance warning devices for use at high speed approaches

  34. Traffic Signals (continued) • Three devices were considered • Flashing strobe light • Flashing RED SIGNAL AHEAD sign • PREPARE TO STOP WHEN FLASHING sign • Each of these were activated at a predetermined time in the signal cycle, usually at a certain time before the commencement of red phase • It has been concluded that the flashing RED SIGNAL AHEAD was the most effective device

  35. Enforcement • The presence of surveillance reduces the unsafe behavior of drivers • Automated enforcement, using red light cameras • An Australian study of the effectiveness of these cameras was undertaken • Crash data from 46 treated sites and 46 control sites were analyzed • The result indicated that there was a 7% reduction in total crashes and 32% reduction in right angle crashes at treated sites, this was significant at 5% level

  36. Signal design and operation • Major efforts being devoted to make existing signal safer • Following geometric and control characteristics have effects on safety • Wider approaches and multiple lanes both associated with higher crash rates for right angle crashes • Increasing the number of lanes at the holding line was associated with higher pedestrian crash rates • Longer approach sight distances were associated with lower crash rates for both left turning vehicles and pedestrians

  37. Signal design and operation (continued) • There are a number of aspects of signal design and operation which analyzed for their effect on safety • Flashing green • Aims to warn drivers of the impending end of the green period • Introducing a flashing green phase in the last 2 or 3 seconds of the green period • It has been used extensively in Israel • It cause significant increase in rear end crashes • There has been two possible responses to flashing green, one being to stop and the other being to accelerate

  38. Signal design and operation (continued) • Starting yellow • A short yellow period before the start of the green • A study about the effect of starting yellow on driver response concluded that there may be a slight benefit in terms of reaction times and capacity • No studies of its effects on safety have been found • Off-peak operation • In off-peak periods the practice in some places is to have signal operate in a flashing yellow mode or flashing red mode

  39. Signal design and operation (continued) • Done for mobility and energy reasons, not bringing a vehicle to a full stop • There are safety disbenefits • A US study found that right angle crashes were significantly over-represented at 4-legged arterial intersections when signals are in flashing mode during night time hours • There was no significant change in rear end collisions • Mast-mounted signal heads • The practice is to use primary signals on the upstream approach, secondary signals on the downstream side, in the median or on the far side of the road and tertiary on downstream but on the curb side

  40. Signal design and operation (continued) • There are also overhead primary signals • To provide adequate advance warning of the approach of the intersection itself • Give earlier indication of the signal aspect • A US study 1991, confirmed the safety benefits of mast-mounted signal heads • 63% reduction in right angle crashes • 25% reduction in total crashes • In some European countries, it is common to provide only the primary set of signals and have a small repeater set mounted on the signal post at driver’s eye level, since the first driver in queue cannot see the primary signals

  41. Signal design and operation (continued) • Demographic factors • Different groups of drivers behave differently in approaching to signalized intersections • Women are more likely to be involved in crashes as a result of misjudgment or lapse of attention • Men are more likely to be involved in crashes as a result of driving too fast • Higher risk taking is associated with • Drivers with prior crashes or violations • Drivers with no passengers • Young drivers • Males • Drivers not wearing seat belts

  42. Signal design and operation (continued) • Elderly drivers take significantly longer to respond, or to make the correct decision when confronted with complex signals such as multiple signal displays • Elderly drivers also • have more difficulty in correctly handling left turns • over-involved in right angle and rear end crashes • Over-involve in crashes involving vehicles turning from the opposite direction

  43. Channelization • Channelization is the use of • Painted road markings • Raised curbs • Traffic islands • Bollards To guide vehicles along a specific path on the approach to and exit from an intersection • Provides positive guidance to drivers • Simplifies the movement

  44. Channelization (continued) • Reduces the room for error • Reduces confusion • Separates the conflict points • The number of decisions required for a driver at any given instance is reduced • Channelization installation or upgrading have significant safety benefits • An Australian study showed 26% reduction in casualty crashes at signalized intersections and 54% reduction at non-signalized intersections

  45. Channelization (continued) • The use of painted channelization at rural intersections in Britain led to 35% crash reduction by protecting a turning vehicle and discouraging overtaking • US studies have found that the provision of exclusive left turn lanes at signalized intersections reduced crashes by 18-40 percent • County Surveyors’ Society in UK, reported that at rural intersections, ‘ghost islands’ (painted channelization had the potential to reduce crashes by up to 50%

  46. Channelization (continued) • Particular guidelines applicable to channelization include • Reduce the general area of conflict • Causing opposing traffic streams to intersect at right angles • Merge traffic stream at small angles • Ensure low relative speeds between conflicting streams • Control the speed of traffic crossing or entering an intersection • By alignment • By restricting width

  47. Channelization (continued) • Provide a refuge for turning or crossing vehicles • Avoid sudden and sharp reverse curves • Reduce the number of islands to the minimum necessary • Ensure safe and effective operation • Provide adequate curve radii and lane width for the prevailing type of vehicle • Provide explicitly for pedestrians and bicyclists • Improve and clearly define alignment of major movements • Prohibit certain turns if necessary

  48. Grade separated interchanges • The key issues in safety aspects of interchanges are • Configuration • Traffic control • Spacing • Heckman and Hayward 1992 found that • Crashes on ramps and connecting roadways increase with traffic volumes and with decreasing curve radius • Particular attention for the needs of trucks on ramps

  49. Grade separated interchanges (continued) • Uphill off-ramps have lower crash rates • Where possible it is preferable for the connecting road to pass over the freeway • Ramps that have lower safety performance • Cloverleaf ramps • Scissor ramps • Ramps leaving from the median edge of the roadway • It is safer to diverge a given number of entering vehicles at two or more on-ramps (or off-ramps) than at a single high volume ramp

  50. Railway crossing • Crashes at railway crossing include • A train strikes a road vehicle • A road vehicle runs into the side of a train • Collision between vehicles on or near the crossing • Associated with a vehicle taking action in response to an approaching train or activation of a warning system • Crashes involving a vehicle colliding with the crossing furniture

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