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--Triskele Jim 19:59, 27 February 2013 (UTC)


EDIT BELOW THIS LINE check for changes made after 6/10/13

North Luzon Expressway's raised plastic transverse rumble strips approaching Balintawak Toll Barrier, Philippines

Rumble strips, also known as sleeper lines or audible lines,[1] are a road safety feature that alert inattentive drivers to potential danger by causing a tactile vibration and audible rumbling, transmitted through the wheels into the car body. Two common uses

Rumble strips are normally a series of narrow depressions or raised elements perpendicular to the direction of travel. A rumble strip is usually either applied in the direction of travel along an edge- or centreline, to alert drivers when they drift from their lane, or in a series across the direction of travel, to warn drivers of a stop ahead or nearby danger spot. In favourable circumstances, rumble strips are effective (and cost-effective) at reducing accidents due to inattention. The effectiveness of shoulder rumble strips is largely dependent on a wide, stable shoulder for a recovery, but there are several other less obvious factors.

Construction and types

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Convex road lines, raised thermoplastic pavement lines

The rumble strip formats are:

  1. Rolled-in, applied to newly laid warm moldable asphalt pavement.
  2. Milled-in, applied to existing hardened asphalt or concrete roads.[2]
  3. Formed, a corrugated form is pressed into fresh concrete.
  4. Raised plastic or ceramic units, fastened to asphalt or concrete pavement and often with a reflector built into the edge. Botts' dots are a common installation.[3]
  5. Raised thermal plastic strips that are melted and fused to the pavement to form a convex traffic line.
  6. "Smart car" virtual shoulder rumble stripes, referred to as a lane departure warning system, available on luxury vehicles and commercial trucks. The alarm is similar to the sound produced when striking rumble strips.
  7. "Smart car" virtual transverse rumble strips to prevent cross-path crashes at intersections are being developed.[4]

Surface-mount raised pavement reflectors are easily removed by the blade on snowplows and thus are not practical in many locations in areas with winter weather, like Canada and the northern United States.[5][6]

Rumble strip uses include:

  1. Transverse rumble strips, used to alert the driver of an upcoming intersection, toll booth or similar hazard. These are placed in the travel lanes where most if not all vehicles will cross them. They may cross the entire road from shoulder to shoulder, or they may only be in the wheel paths. [7]
  1. Shoulder and centerline rumble strips are used to reduce lane departure crashes, such as [[head-on collision}}s and run-off-road collisions. They alert distracted or drowsy drivers that they are leaving the roadway or crossing the centerline. In this application, they are narrower and outside of the wheelpaths.[8]

History

[edit]

Rumble strips were first implemented on the Garden State Parkway in New Jersey in 1952.[9][10]

Initially, shoulder rumble strip installation focused on freeways. DUring paving, rumble strips were pressed into hot, soft asphalt using a modified roller on a pavement rolling machines. Later, paving contractors modified pavement milling machines to grind rumble strips into existing hardened asphalt pavement. Specifically designed commercially available machines followed. The development of ceramic and plastic raised systems enabled installation on concrete pavement highways. This allowed narrower rumbles trips better suited for use along the centerline of two way roadways.

As rumble strip installation became more widespread, it was sometimes controversial. Residents near urban freeways complain of noise at night as vehicles change lanes; or when vehicles strike the transverse rumble strips. Bicyclists find rumble strips at best uncomfortable to ride on, and at worst express concerns about possible loss-of-control crashes. U.S. and Canadian guidelines have minimum standards for installation on known cycling routes. In 2009, in Michigan, the Amish claimed the shoulder rumble strips were dangerous for horse-drawn carriages and successfully lobbied to have them paved over. In 2010, Kansas has considered removing shoulder rumble strips from an Interstate Highway to allow buses to travel on shoulder during periods of traffic congestion.

Effectiveness

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transverse rumble strips

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shoulder rumble strips

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Centerline rumble strips

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Disadvantages

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Noise

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Pavement degradation

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Non-motorized traffic

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Bicyclists

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Horse-drawn vehicles

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On-road and run-off-road accidents

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The single-vehicle crashes are classified into two groups: run-off-road (ROR), and on-road (OR) crashes in which the vehicle remains on the road after the crash. ROR crashes can account for up to 70% of the fatal single-vehicle crashes.

ROR crashes are due to inattention, speeding, traction loss, overreaction, crash avoidance, and mechanical failure.[11] Rumble strips only prevent ROR crashes due to inattention.

Research indicates that 47% of ROR's exited the highway to the left; while 53% exited the highway to the right.[5]

Excessive speed and curves

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Rumble strips are ineffective in preventing run-off-road accidents due to excessive speeds.[12] Highway curves are super-elevated (banked) to assist vehicles that are traveling the speed limit to stay centered in the lane. Also, the asphalt pavement in curves tends to be "polished" from the lateral tire forces of vehicles exceeding the design speed (posted speed limited) and this reduces the traction in turns.[13] In the same manner, if a speeding vehicle happens to drift over the rumble strip in a curve those tires will experience traction loss particularly if rumble strip depressions are filled with water, slush or ice.[14]

Inattentive driving

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A FHWA sponsored study states: "Driver inattention comes in many forms including distraction, daydreaming/competing thoughts, fatigue/drowsiness, and alcohol/drug impairment."[15]

Early evening low alcohol intake also worsens sleepiness-related driving impairment.[16]

In the U.S., the percentage of fatally injured drivers tested and found to be legally impaired (BAC > 80 mg %) is about 33%. In the U.S., the percentage below 80 mg%, but above 0 is 5% (2008), so alcohol is involved in about 38% of all fatalities.[17] Canada has similar statistics.[18]

Crash migration

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A FHWA sponsored study wrestled with moral dilemma of rumble strips keeping "unsafe drivers" (which includes impaired drivers) on the highway. "This group of unsafe drivers temporarily saved by the rumble strips may have caused some multiple-vehicle crashes involving harm to innocent victims to occur downstream from the treated site where no rumble strips existed. Unfortunately, as noted above, an examination of downstream crashes could not be conducted."[15]

A 2008 Swedish study using a driving simulator and 35 sleep deprived drivers concluded: "The main results showed an increase in sleepiness indicators from start to before hitting the rumble strip, an alerting effect in most parameters after hitting the strip. The alertness enhancing effect was, however, short and the sleepiness signs returned 5 min after the rumble strip hit. Essentially no effects were seen due to type of strip."[19]

A 2003 Montana study suggested that on Interstates shoulder rumble reduced the roll-over accident rates but the severity of unprevented roll-over accidents increased. This was thought to be due to the rumble strip "scaring" sleeping drivers to the extent that they overreacted. This problem was more pronounced on primary highways (that have narrower shoulders) with rumble strips.[14]

These support that crashes can be migrated vehicle-to-vehicle, season-to-season, location-to-location, further downstream of rumble strips on the highway system, and prevented-to-unprevented crash severity.

Behavior adaptation

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Rumble strip may gradually encourage inattentive driving – thereby partially negating any safety benefits in the long term. This is referred to as "behavior adaptation".[20][21]

A 2006 U.S. study suggested that airbags and antilock brakes lead to unsafe driving.[22] A 2007 Canadian study suggested that unsafe drivers are habitual, and that unsafe driving is increasing.[23] A 2009 Canadian study indicated that, after a steady decline, drinking and driving has been on the increase since 2004.[24] These support the migration and behavioral adaptation rumble strip concerns.

A safe driver population has more potential for negative behavior adaptation than an extreme unsafe driver population; whereas, an extreme unsafe driver population has more potential for positive behavior adaptation than a safe driver population.

Accident rates and profile

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Different jurisdictions have different accident and fatality rates, as a function of various factors such as climate, road layout, demographics, educational programs, level of policing, driver attitudes toward night driving, promptness of emergency response, and level of medical intervention.[11] For example, the 2006 Canadian motor vehicle fatality rate per province varied between 8.8 and 26.8 per 100,000 licensed drivers per year, with a national average of 13.[25] The 2008 U.S. rate is 20.05.[17] Installing rumble strips on a highway with a relatively low accident rate and low proportion of accidents due to inattention will be relatively ineffective, even if the highway has 12 foot paved shoulders.

The FHWA states: "Long sections of relatively straight roadways that make few demands on motorists are the most likely candidates for the installation of shoulder rumble strips." The degree of engagement of a highway affects the accident rate. Implied in this statement is that highways that are twisty and hilly with a variable foreground have low rates of accidents due to inattention, and are therefore not likely candidates for the installation of rumble strips.[12] Installing rumble strips along a highway that is highly engaging, with a narrow shoulder, a low accident rate, and relatively low proportion of accidents due to fatigue or inattentive driving would have questionable value.

Diminishing marginal returns

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In addition, safety improvements are not linear; there are diminishing marginal returns with a safer driver population, in which it is more difficult to reduce the accident rate. Within the industrialized countries the rate varies between about 8 and 27 (per 100,000 licensed drivers per year).

"Safety improvements are usually subject to the law of diminishing marginal returns. This means that for every improvement of a fixed amount, the safety benefit gained decreases a little each time. For example, increasing the width of the median from 50m to 60m will decrease the number of collisions less than increasing it from 10m to 20m. Eventually, a width will be reached at which widening the median further cannot be justified because the improvement in safety is too small."[26]

When the accident rate is close to the baseline of 8 its because there are already several factors pushing it down so adding another safety factor (initiative) will only will only yield a very small improvement. Installing rumble strips on a highway with a high accident rate close to 27 would yield a relatively high accident reduction. These, of course, assume the shoulder is adequate for a recovery.

Deterioration

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Climate

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Traction sand filled shoulder rumble strip. The sand is "cemented" in-place and is not easily removed by truck traffic.

Climate is another factor that affects the success of a rumble strips installation. If they are installed in a northern climate, they may be filled or partially filled with a deicing salt and traction sand mixture. They may also be filled with ice. This is a particular concern in regions with freeze-thaw cycles requiring frequent deicing. Furthermore, strips filled with water, snow, slush, and ice, and may cause or aggravate occasional accidents. Generally, turbulence and vibration from trucks keep rumble strips clear of debris and ice, but this process may take several days.[6] Moist traction sand tends to cake together or freezes, and is not easily dislodged by truck traffic. This is problematic on low-volume highways with frequent deicing, and can significantly reduce the effectiveness of rumble strips in winter months.

When rumble strips are installed on a very narrow paved shoulder sometimes sand and gravel can fill the rumble strip which is usually a problem in the winter and early spring.

If the snow-cover is substantial, then the shoulder (including the rumble strip) is usually partially snow-covered as snow plow's wing-blade doesn't clear the entire shoulder. Vehicles going off the road usually collide with the shoulder snow bank or go into a snow-filled ditch which reduces the possibility of serious damage and injury. In these situations, the rumble strip effectiveness can be negated but the crash implications are as well.

Wildlife

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Deicing salt filled and stained rumble strip. The rock salt has been "cemented" in place

Wildlife-vehicle collisions can be a significant problem when large animals are involved such as moose, elk and deer resulting in serious vehicle damage and injury and fatalities.[27][28] Separate studies in New Hampshire (U.S.) and Quebec (Canada), of radio-collared moose found that home ranges were associated with salt licks formed by road salt runoff. These roadside salt licks were thought to increase moose-vehicle collisions.[29][30][31] Normally, salt would make its way off the pavement onto the gravel shoulder and into the soil, however, rumble strips will retain and create a salt lick on the road surface. Loose rock salt in the rumble strip subjected to evaporating moisture will cake and accumulate and is not easily dislodged by truck traffic.

Pavement deterioration

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Generally, deterioration of the shoulder asphalt pavement due to rumble strip installation is not a problem. However, if the sub-grade under the CSRS is poorly compacted or has poor drainage characteristics; or the gravel shoulder has eroded, crack(s) may form in the CSRS. Sand tends to fall into these cracks resulting in "jacking" of the cracks. Water percolates vertically down through the soil, but it also creeps horizontally under the paved shoulder. This may be a particular problem with narrow paved shoulders in regions with frequent freeze-thaw cycles that may result in frequent frost-heaving of the paved shoulder.[32] U.S. and Canadian guidelines recommend not installing rumble strips in asphalt pavement displaying cracks to avoid excessive break-up of pavement. It is also recommended that rumble strips be inspected in summer months for cracking, potholing, water ponding and snow plow damage. If necessary, structural problems should be repaired.[6] If the cracks become wide enough grass and weeds will grow in the cracks accentuating the deterioration.

The centerline of highway has a pavement joint and milled CLRS are installed over this joint which make pavement more vulnerable to deterioration. Truckers have reported deterioration of the joint and the CLRS.[5]

Continuous shoulder rumble strips (CSRS)

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Montana undertook an extensive 10 year multi-site study of the effectiveness of CSRS on Interstate and primary highways (that are both divided). This study investigated the severity of accidents which sets it apart from previous studies. The results indicated a 14% reduction in accidents on Interstate highways; however the effectiveness on primary highways indicated both improvements and worsening and the results considered inconclusive. It was found that "roll-overs" decreased in number, but increased in severity. The study only considered accidents in dry and wet conditions, not snow and ice.[14]

The FHWA undertook a multi-state study involving test sites from Illinois and California. The Illinois component indicated crash reduction from 7.3% to 21.7%. The California component indicated crash reductions of 7.3%. This study also indicated an overall reduction of about 14%.[15]

The 1997 New York State Thruway study indicated a 65% to 70% reduction.[6] However, in a 1999 New York Times article regarding the New York State Thruway study, an official stated: "The experiment is not pure, however, because Troop T has also been conducting a campaign to reduce drunken driving and increase seat-belt use, both of which would also reduce the number of fatal vehicle accidents" and "From 10 to 24 percent of crashes are estimated to involve fatigue or inattention of some kind, but these numbers are based on guesswork."[33]

Despite this, the New York State Thruway study indicating a 65% to 70% reduction continues to be cited in literature.[6][14]

New Zealand used rumble strips in small applications since the late 1980s, and started a larger program in 2004. Research in the country indicated that lane delineation with rumble strips reduced crashes by an average of 27% over all crash types and studies, with types of crashes such as "run off road" being reduced by up to 80% in some studies. Centre-line rumble strips showed similar effects. However, it appears that there were other crash reduction initiatives that may have contributed to the relatively sizable results.[34]

The effects remained even after road users had become accustomed to the feature, while other road safety measures (when studied at specific installations) often showed declining effectiveness over time.[34] Cost-benefit analysis showed that even on relatively low-volume roads, the costs of applying the markings were quickly exceeded several-fold by the economic benefits of improved road safety (as counted by the reduction of accident rates weighted against the average social costs of a crash).[34]

Further research in New Zealand led to recommendations that strip edge lines and centre lines be marked over extended lengths of road, rather than just at focal points and accident black spots. Apart from the safety benefits of providing a consistent road environment, continuous markings provide valuable alerts to drivers long before the more common accident spots.[35]

Pennsylvania Turnpike study and the one-third "rule-of-thumb"

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The one-third reduction rate and the Pennsylvania Turnpike Study (with a 60% reduction) are the rule-of-thumb and the classic study, but these can be misleading as CSRS do not have a "fixed" effectiveness that may be applied to any highway.[36]

A one-third reduction rate is commonly cited and is based on an average of early studies. It includes the New York State Thruway and Pennsylvania Turnpike results which produced a skewed result non-representative of typical situations.[3][6]

A 1999 FHWA study concluded that "a best guess" might be 20% to 30% reduction in single-vehicle run-off-road crashes on rural freeways, with less effective on urban freeways.[15]

It should be noted that almost all before-and-after studies are based on Interstate (freeway, turnpikes, thruways) test sites have minimum 12-foot paved shoulders and very high accident rates due to inattention.

The collision reduction attributed to the installation of CSRS is mainly a function of stable shoulder width, accident rate and profile, climate and diminishing marginal returns.

Shoulder width

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Research has found that on rural freeways, rumble strips are much more effective when placed at or near the edgeline than when placed closer to the shoulder edge. Edgeline rumble strips can be expected to reduce crashes by 28.8%, and non-edgeline rumble strips only reduce crashes by 8.9%.

On two-lane roads, there is little difference in effectiveness between edgeline and non-edgeline rumble strips, with crash reduction factors of 39.2% and 41.9%, respectively.[37] FHWA now recommends rumble strips on two lane roads if the edge of shoulder is more than 13 feet from the centerline, especially if the road has high volumes, poor geometry, or a history of run-off-road crashes.[38]

The 2003 Montana study stated: "In certain cases, rumble strips may act only as a harbinger (warning) of an impeding crash. Such a situation is much more likely to arise where less shoulder is available for recovery." [14]

Recovery zone condition

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A concern about highways with narrow paved shoulders is the condition of the adjacent gravel shoulder. Sometimes, the paved and gravel shoulders are combined as the "recovery zone" beyond the rumble strip. However, if the gravel is loose, soft, non-level, eroded, or there is an "edge-drop" from the pavement to the gravel the gravel shoulder portion will be ineffective for recovery, especially at highway speeds. When a vehicle's tires sink into a soft shoulder compromising vehicle handling it is known as "vehicle tripping".[36]

Virtual rumble strips require an adequate recovery zone as well.

The "classic" one-car crash

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"The "classic" one-car crash results when a vehicle slowly drift to the right, hits dirt or rumble strips on the right shoulder of the road, and the driver becomes alert and overreacts, jerking the wheel left to bring the vehicle back onto the road. This motion causes the left front tire to strike the raised edge of the pavement at a sharp angle, often causing a rollover or a swerve into oncoming traffic. Why "classic?" Because investigating officers will tell you they see this type of mishap so often, it is now a cliché." [39] Raised edges of pavement (or "edge-drops") were once common, but are now recognized as a hazard; it is now standard practice to level the gravel shoulder with the pavement, although edge-drops may reform due to erosion. This "slowly drift to the right" scenario applies to jurisdictions with right-hand traffic, so in jurisdictions with left-hand traffic it would be a "slowly drift to the left" scenario.

This implies that a sleeping driver often does not react and begin to recover until all four wheels have struck a rumble strip; if the paved shoulder is narrower than the width of the wheel-base, a rumble strip may not prevent a sleeping driver from going off the road.

On a single lane highway, an overreacting driver has less room to regain control which may exacerbate their initial overreaction after striking the strips resulting in a roll-over or head on collision. An accident investigating officer stated: "It's consistent with someone who falls asleep or overreacts to the rumble strips," which implies this is not the first time the officer has witnessed this situation.[40] Note that in the KATU.com article photograph (in the upper left-hand corner) of the accident scene, the passenger-side tire print in the soft shoulder that suggests that all four wheels passed over the rumble strip before the driver attempted the unsuccessful recovery.[41]

Effectiveness on different classes of highway

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Recent before-and-after studies suggest that the effectiveness of CSRS on Interstate highway (or freeways or thruways) with 12 foot paved shoulders is about 7% to 21% with an overall effectiveness of about 14%.

The effectiveness of CSRS on the lower standard primary highways (that are also divided) hasn't been given the same consideration as those on Interstate highways. The 2003 Montana study suggested that CSRS on primary highways may result in either worsening or improvement of crash rates. This may be due to variation in recovery zone width and condition and other factors. It indicated that unprevented crash severity may worsen. The results were considered "inconclusive". "The supposed differences from Interstate highways likely stem from the simple fact that primaries often have smaller shoulders than do Interstates." [14]

Secondary highways are single-lane highways. It appears that there are no before-and-after CSRS studies for single-lane highways. It follows that CSRS on single-lane undivided highways would be less effective than those on primary highways. The most serious problem would be increase in crash severity. Also, there is the concern of drivers sometimes overreacting and crossing the centerline resulting in a head-on collision.[41] The recovery zone width and condition of single-lane highways can vary greatly.

Centerline Rumble Strips

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Centerline Rumble Strips are applied to single lane undivided highways to help prevent head-on collisions. These are often milled.

A 2005 NCHRP study concluded that overall motor vehicle crashes at sites treated with Centreline Rumble Strips were reduced overall by 14%." [5] In these situations the opposite lane and any paved shoulder would function as a generous recovery zone. However, this study didn't investigate changes in crash severity as the 2005 Montana study.

It is interesting that the Centerline Rumble Strip reduction value is the same as the 2005 Montana CSRS study that indicated a 14% reduction in accidents on Interstate highways. This supports that the overall effectiveness of CSRS with a generous recovery zone is about 14%.

Ice and slush filled rumble strips can be a concern but particularly so be milled centerline rumble strips and for that reason some jurisdictions are reluctant to install them.[42]

Continuous Lane Rumble Strips (CLRS)

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CLRS are applied to multiple lane highways to help prevent vehicle from drifting into the adjacent lane and possibility colliding with an overtaking vehicle. These are typically a raised reflective system.

Actual vs. isolated CSRS and centerline rumble strips effectiveness

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Given behavior adaptation and migration, the current rigorous Interstate effectiveness of 14% and CLRS on single-lane highways effectiveness of 14% could be over-estimations of the actual "big-picture" reduction. In certain situations, such as an engaging single-lane highways that typically have narrow shoulders, high precipitation, in a northern climate with frequent freeze-thaw cycles, rumble strip effectiveness may be negative.[14]

As before-and-after studies become broader and more sophisticated it appears the reduction estimates for both CSRS and centerline rumble strips are less impressive. This may be due to the initial installations were on highways that had been identified as having very high accident rates due to inattention. Also, there may have been other accident reduction campaigns in concert with rumble strip programs."[33]

Also, as lane departure warning systems become more widespread the physical CSRS, centerline rumble strips CLRS may be become increasingly redundant.

Transverse Rumble Strips (TRS)

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Transverse rumble strips (TRS) may be used to warn drivers: of the need to stop (e.g. intersections, toll plazas); the need to slow down; the need to change lanes; of a change in roadway alignment; that they are leaving the traveled way; upcoming construction zones; wildlife crossings; and other potentially unexpected conditions.[3] [43]

As a speed reduction measure TRS have been marginally successful. A 2003 Texas study concluded: "However, the actual reductions in speeds have been in the range of 2 to 8 mph (3.2 to 12.9 km/h), which may be barely perceptible to the traveling public. There have been no studies that evaluate the reduction of excessive speeds." [3]

As a construction zone safety measure the effectiveness appears unclear. A 2007 Minnesota study indicated: "While the study concluded that transverse rumble strips offer a lowcost and easy-to-install option, they “did not seem to be successful at reducing approach speeds at the project sites.” [44] A 2005 Maryland study stated: "In conclusion, although in the present study rumble strips did not produce the desired speed reduction effect, its use for work zone applications is still highly encouraged; though, not as a speed control measure but as a driver’s attention-catching device." [45]

As an approach stop-control crash reduction measure they have proven successful. The 2003 Texas indicated: "The majority of studies found reported large reductions (40 percent to 100 percent) of accidents after installing transverse rumble strips." [3]

In Ghana, rumble strips running across the entire carriageway were installed at Suhum Junction on the main Accra-Kumasi highway and reduced crashes by about 35% and fatalities by about 55%. By reducing speeds the environment for and safety of pedestrians was improved with a decline in the "hit pedestrian" crash rate of 51%. "While the enforcement of speed limits by traffic police may not be affordable for most developing countries, rumble strips and speed humps were found to be effective on Ghanaian roads." [46]

A 2009 FHWA intelligent systems study suggested that a combined infrastructure-based and in-vehicle warning could be highly effective in reducing crossing path crashes and fatalities at signalized intersections.[4]

Removal and opposition

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In February 2010, Johnson County, KS. (U.S.), tabled legislation to allow buses to travel on the paved shoulder (which is currently rumble stripped) when traffic slows to less than 35 mph (56 km/h). "The start-up plan estimates costs at between $17.6 million and $20 million, including $2.4 to remove rumble strips along the shoulder of I-35." [47] "The Kansas House Transportation Committee says it would be modeled after a similar one in Minneapolis, Minn."[48][49][50]

Some residents living close to either newly installed lane or transverse rumble strips have complained about noise levels and were successful in having them removed at considerable expense. In 2004, the Town of Chapel Hill, NC, U.S., had transverse rumble strips removed as measured noise exceeded the Town's Noise Ordinance. "General noise levels close to the sidewalk varied from 60 to 77 decibels depending on the type and speed of traffic passing over the rumble strips. These noise levels exceed the generally applicable 60 decibel noise level allowed by the Town’s Noise Ordinance during nighttime hours." [51] In 2005, the London Borough of Bromley removed transverse rumble strips after residents complained of the excessive "machine gun fire" noise.[52] In 2010, Reno County plan to remove rumble strip from a roundabout after residents complained about excessive noise levels.[53]

The Transportation Association of Canada and US FHWA guidelines basically require that a width of 1.5 m (5 ft) of clear paved shoulder between the outside of the rumble strip and the edge of pavement is adequate to provide cyclists with a clear travel path.[6][12]

However, in situations of parked vehicle on the shoulder, debris on the shoulder, or downhill sections even the 1.5 m (5 ft) clear path requirement rumble strips presents a significant hazard particularly if the pavement is wet. The argument that rumble strip help protect cyclists is puzzling as inattentive drivers' vehicles generally pass entirely over the rumble strip before recovery.

Other related FHWA guidelines are: "Rumble strips should not normally be used in urban or suburban areas or along roadways where prevailing speeds are less than 80 km/h (50 mph)." and "All responsible agencies should work in cooperation with bicycle groups, enforcement agencies, emergency groups and other roadway users, to develop policies, design standards and implementation techniques that address the safety and operational needs of all roadway users." and "To provide a clear area beyond the rumble strip for bicycle travel, highway maintenance agencies should periodically sweep shoulders along identified bicycle routes of high bicycle usage."[12]

In the United States, the 1999 American Association of State Highway and Transportation Officials (AASHTO) Guide for the Development of Bicycle Facilities recommends minimum standards for road shoulders receiving rumble strips to accommodate all users of the roadway and make best use of funds.[54]

Cycling complaints

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Numerous U.S. and Canadian cycling associations have complained about encroachment of rumble strips and one club even launched a lawsuit to have them paved over and an online petition to halt the practice. [55] [56] [57] [58] [59] A 2005 Quebec study concluded: "Based on the results of the analyses, it was not possible to recommend a type of rumble strip that would provide sufficient warning to drivers who encroach on the shoulder while remaining safe for cyclists who ride over it."[60] A 2003 Montana study suggested: "It was also recognized that bicyclists cannot operate on shoulders with rumble strips and it was indicated that shoulders would be swept as needed."[14]

Once a section of highway with narrow paved shoulders is rumble-stripped familiar cyclists tend to avoid it, but unsuspecting cyclists occasionally have serious accidents.[61] Much bicyclist opposition to rumble strips stems from situations in which no quantitative data is used to justify their installation or installation is not in accordance with guidelines. Rumble strips on narrow shoulders force cyclists into the travel lanes, where it is less safe to ride.[55][56][57][58][59] Furthermore, this scenario forces drivers to make an otherwise unnecessary lane change to go around cyclists and there is a correlation with frequency of lane changes and accidents. "According to the National Highway Traffic Safety Administration, 9 percent (533,000) of all accidents occurred when vehicles were changing lanes or merging."[62] In certain incidents, a vehicle attempting to avoid cyclists (without striking the cyclists) may go off the road or even sideswipe a passing or an oncoming vehicle. Center-line rumble strips are a concern for cyclists as well, as motorists are less inclined to cross the centerline to provide sufficient space when passing bicyclists.[5]

Rumble strips are very inexpensive to install, so there is concern that some installations are frivolous. The 2009 economic stimulus infrastructure spending in the U.S. and Canada has raised concerns that many new shoulder rumble strips will be frivolous as well. [55][56][57][58][59]

Amish lobby

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In 2009 in St. Joseph County Michigan, after a lobby by the local Amish community a new $20,000 rumble strip installation was removed at a cost of $275,000 to the taxpayer. "M-DOT says they are not removing the strips just to appease the Amish. They say it is far more dangerous to have horses jumping out into the road that [sic] it is to not have the rumble strips on the road." [63]

See also

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References

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  1. ^ "Reg 323A, New South Wales Road Rules 2008". Retrieved 26 April 2012.
  2. ^ "Corridor H Contract Plans". Michael J. Baker, Inc. p. 4. Archived from the original (PDF) on May 24, 2010. Retrieved May 24, 2010.
  3. ^ a b c d e Effectiveness of Rumble Strips on Texas Highways, First Year Report(2003)
  4. ^ a b The Effects of In-Vehicle and Infrastructure-Based Collision Warnings at Signalized Intersections
  5. ^ a b c d e Centerline Rumble Strips NCHRP Synthesis 339, 2005
  6. ^ a b c d e f g Transportation Association of Canada - Best Practices for the Implementation of Shoulder and Centerline Rumble Strips(2001) Synthesis of Practice No. 8
  7. ^ "Safety Evaluation of Transverse Rumble Strips on Approaches to Stop-Controlled Intersections in Rural Areas". Federal Highways Administration. May 2012. Retrieved 6/10/2013. {{cite web}}: Check date values in: |accessdate= (help)
  8. ^ Shoulder Rumble Strips: A Method To Alert "Drifting" Drivers - Wood, Neal E., Pennsylvania Turnpike Commission, January 1994
  9. ^ "Garden State Parkway". Retrieved 2007-07-09.
  10. ^ ""Singing" Safety Lanes Provide Warning for Motorists". Popular Mechanics: 139. 1953. Retrieved 30 April 2013. {{cite journal}}: Unknown parameter |month= ignored (help)
  11. ^ a b Factors Related to Fatal Single-Vehicle Run-Off-Road Crashes, NHTSA, Nov. 2009
  12. ^ a b c d Roadway Shoulder Rumble Strips, T5040.35, Dec 20, 2001
  13. ^ Case Highway Design Note 2/01, Horizontal Curves
  14. ^ a b c d e f g h An Evaluation of Shoulder Rumble Strips in Montana (MDoT, Research Section, 2003)
  15. ^ a b c d Safety Evaluation of Rolled-In Continuous Shoulder Rumble Strips Installed on Freeways, FHWA, Dec. 1999
  16. ^ Barrett, PR; Horne, JA; Reyner, LA (2005). "Early evening low alcohol intake also worsens sleepiness-related driving impairment". Human Psychopharmacology. 20 (4): 287–90. doi:10.1002/hup.691. PMID 15912483. S2CID 30836683.
  17. ^ a b FARS-Fatality Analysis Reporting System
  18. ^ Smashed: A Sober Look at Drinking and Driving (Transport Canada)
  19. ^ Anund, A; Kecklund, G; Vadeby, A; Hjälmdahl, M; Akerstedt, T (2008). "The alerting effect of hitting a rumble strip--a simulator study with sleepy drivers". Accident; Analysis and Prevention. 40 (6): 1970–6. doi:10.1016/j.aap.2008.08.017. PMID 19068302.
  20. ^ SciTopics Research Summaries by Experts, Sept. 2008
  21. ^ Behavioral Adaptation, Why Safety Features Don’t Always Increase Safety (Claims Advisor), Oct. 2007
  22. ^ Airbags, Antilock Brakes Not Likely To Reduce Accidents, Injuries, Purdue University, Sept. 2007
  23. ^ Insurance-Canada.ca, Sept. 2007
  24. ^ TIRF-Are Canadians Changing Their Drinking and Driving Habits?, Dec. 2009
  25. ^ Transport Canada, 2006 - Casualty Rates
  26. ^ Report of the Highway 407 Safety Review Committee
  27. ^ Wildlife-Vehicle Collision Reduction Study: Report To Congress, Publication No. FHWA-HRT-08-034, Aug 2008
  28. ^ Update of Data Sources on Collisions Involving Motor Vehicles and Large Animals in Canada, Transport Canada, June 2006
  29. ^ Wildlife-Vehicle Collision and Crossing Mitigation Measures: A Toolbox for the Montana Dept of Transportation, May 2007
  30. ^ Reducing Moose–Vehicle Collisions through Salt Pool Removal and Displacement: an Agent-Based Modeling Approach, Ecology and Society, 2009
  31. ^ U.S. FHWA, Public Roads, Of Moose and Mud, Sept/Oct 2005
  32. ^ FHWA, Public Roads, Rumbling Towards Safety, Sept/Oct, 2003 (Photo 9)
  33. ^ a b New York Times, Autos, The Asphalt Rumble , June 26, 1999
  34. ^ a b c The hidden persuaders - Contractor magazine, Vol 30 No 9, October 2007
  35. ^ The Usability and Safety of Audio Tactile Profiled Road Markings - Executive Summary, Research Report 365, Land Transport New Zealand, February 2009. Accessed 2009-03-15.
  36. ^ a b Run-off-Road Collisions - Description of Strategies, circa 2003
  37. ^ D. J. Torbic; et al. (2009). NCHRP REPORT 641: Guidance for the Design and Application of Shoulder and Centerline Rumble Strips. Washington, D.C.: Transportation Research Board. p. 85. {{cite book}}: Explicit use of et al. in: |author= (help)
  38. ^ "Consideration and Implementation of Proven Safety Countermeasures". Federal Highways Administration. July 10, 2008. Retrieved 11/5/11. {{cite web}}: Check date values in: |accessdate= (help)
  39. ^ Road trip America (RTA) Rule 33: Avoid the Single-Vehicle Collision
  40. ^ New York Times, Korean Survivors of Van Crash Help to Bury Their Dead, August 3, 1995
  41. ^ a b KATU.com, Woman killed, two hurt in head-on crash, Aug 28, 2007
  42. ^ Safety Evaluation of Centerline Rumble Strips: A Crash And Driver Behavior Analysis
  43. ^ Wildlife Crossing Designs and Use by Florida Panthers and Other Wildlife in Southwest Florida
  44. ^ Transverse Rumble Strips, MInnesota Department of Transportation(2007)
  45. ^ Use of Temporary Transverse Rumble Strips in Work Zones , MSHA(2005)
  46. ^ Afukaar, Francis K. (2003). "Speed control in developing countries: issues, challenges and opportunities in reducing road traffic injuries". Injury Control and Safety Promotion. 10 (Mar–Jun, 1–2): 77–81. doi:10.1076/icsp.10.1.77.14113. PMID 12772489. S2CID 13639085.
  47. ^ County Pushing for Bus Service on Shoulder of I-35, Daily Me, Feb 2010
  48. ^ Bill Would Allow Buses to Drive on Shoulder, NBC Action News, Feb 2010
  49. ^ Bus-only shoulders in the Twin Cities EDF, April 2009
  50. ^ Bus Only Shoulders in the Minneapolis/St. Paul Area, Minnesota Department of Transportation (circa 2002 or later)
  51. ^ Memo, Agenda #4c, removal of Rumble Strips on Westbound Travel Lanes of NC 54 Approaching Hamilton Road, Jan 2004
  52. ^ London Borough of Bromley, Agenda Item No. 5, Dec 5, 2005
  53. ^ Rumble Strips Near Roundabout to be Removed, hutchnews.com, 2/3/2010
  54. ^ A Guide for the Development of Bicycle Facilities, AASHTO(1999)
  55. ^ a b c New York Bicycle Coalition
  56. ^ a b c British Columbia Cycling Coalition
  57. ^ a b c Bicycle Colorado
  58. ^ a b c Rochester Bicycling Club
  59. ^ a b c Westchester Cycling Club
  60. ^ Testing and Evaluation of Rumble Strips Separating Traffic Lanes and Bicycle Lanes on the Shoulder Roadway, Transports du Québec
  61. ^ NYC Cop Injured in Rumble Strip Accident, Nov 3, 2009
  62. ^ Proper Lane Changes to Help Reduce Accidents, Allstate
  63. ^ WWNT.com Rumble strips removed after the Amish say they're dangerous, Aug 20, 2009
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Category:Road traffic management Category:Road infrastructure