Guardrail with slidable impact-receiving element

Information

  • Patent Grant
  • 6173943
  • Patent Number
    6,173,943
  • Date Filed
    Wednesday, April 22, 1998
    26 years ago
  • Date Issued
    Tuesday, January 16, 2001
    23 years ago
Abstract
A guardrail includes an array of vehicle-deflecting rails secured to an array of posts extending along a roadway. An impact-receiving element is slidably mounted to the forward end of the array of rails, and this impact-receiving element includes a vehicle-engaging portion having a first frontal area that is substantially greater than a second frontal area characteristic of the first end of the array of rails. A column is interposed between a forward portion of the impact-receiving element and the first post to apply initial compressive forces in a collision directly to the first post.
Description




BACKGROUND




The present invention relates to guardrails of the type that are placed alongside a roadway to redirect a moving vehicle that has left the roadway.




Modern guardrails are relied on for two separate functions that are to some extent in tension with one another. First, the guardrail preferably has adequate tensional strength in the longitudinal direction that a vehicle striking an intermediate portion of the guardrail at an oblique angle will be prevented from passing through the guardrail and redirected along the length of the guardrail. This function requires considerable tensional strength.




Second, the guardrail preferably slows a vehicle that strikes the end of the guardrail at a suitable rate such that excessive decelerations are not applied to the vehicle and the guardrail does not impale the vehicle.




Various prior-art approaches have been suggested for accommodating these two separate functions of guardrail design. See for example, Sicking U.S. Pat. Nos. 5,547,309 and 5,407,298, Mak U.S. Pat. 5,503,495, and U.S. patent application Ser. No. 08/990,468 (U.S. Pat. No. 5,967,497), filed Dec. 15, 1997, assigned to the assignee of the present invention.




The present invention is directed to improvements in guardrails that further reduce any tendency of the guardrail to impale an impacting vehicle while maintaining a desired level of longitudinal tensional strength.




SUMMARY




The present invention is defined by the following claims, and nothing in this section should be taken as a limitation on those claims.




By way of introduction, the preferred embodiment described below includes a guardrail having an array of vehicle-deflecting rails secured to an array of posts. This embodiment further includes an impact-receiving element that is slidably mounted to the forward end of the first rail. This impact-receiving element includes a vehicle-engaging portion having a frontal area substantially greater than the frontal area of the end of the first rail. Because the impact-receiving element is slidably mounted to the first rail, an impacting vehicle initially accelerates the impact-receiving element, without substantially accelerating or deforming the remaining rails. Since the frontal area of the impact-receiving element is substantially greater than that of the first rail, impact forces on the vehicle are spread. These two features cooperate to reduce any tendency of the guardrail to impale the vehicle.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a perspective view of a guardrail that incorporates a presently preferred embodiment of this invention.





FIG. 2

is an enlarged perspective view of the front portion of the guardrail of FIG.


1


.





FIG. 3

is a perspective view of an impact-receiving element included in the embodiments of

FIGS. 1 and 2

.





FIG. 4

is a side view of a guide rail included in the impact-receiving element of FIG.


3


.





FIG. 5

is a top view taken along line


5





5


of FIG.


4


.





FIG. 6

is a rear view taken along line


6





6


of FIG.


4


.





FIG. 7

is a cross-sectional view taken along line


7





7


of FIG.


2


.





FIG. 8

is a cross-sectional view taken along


8





8


of FIG.


2


.





FIGS. 9

,


10


and


11


are perspective views of three posts included in the embodiment of FIGS.


1


-


8


.





FIG. 12

is a cross-sectional view taken along line


12





12


of FIG.


1


.











DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED EMBODIMENTS




Turning now to the drawings,

FIG. 1

shows a perspective view of a guardrail


10


that incorporates a presently preferred embodiment of this invention. The guardrail


10


is mounted alongside a roadway R, and the forward end


12


of the guardrail


10


faces an anticipated impact direction D.




As shown in

FIG. 1

, the guardrail


10


includes an array of rails


14


secured to an array of posts


16


. The posts


16


are partially buried in the ground, and they are numbered consecutively, starting with a first post


18


at the front end of the guardrail


10


, followed by a second post


20


, and so forth. In this embodiment, the first and second posts,


18


,


20


are received in foundation tubes


22


provided with soil plates


24


. Additionally, the first and second posts


18


,


20


are interconnected by a strut


26


. These features cooperate to immobilize the first and second posts


18


,


20


at ground level, thereby enhancing the tendency of the first and second posts


18


,


20


to break off cleanly at ground level in an axial impact.




As best shown in

FIG. 2

, the forward-most rail


14


supports at its forward end


28


an impact-receiving element


30


. This impact-receiving element


30


is shown in perspective view in FIG.


3


. The forward end of the impact-receiving element


30


takes the form of a vehicle-engaging portion


32


that is bolted in place to the forward end of a guide rail


34


.




The guide rail


34


is shown in

FIGS. 4

,


5


and


6


. As best shown in

FIG. 6

, the guide rail


34


defines two axially extending ridges


36


, separated by an axially extending valley


38


. Such rails are conventionally known in the art as W-beams, and the guide rail


34


has generally the same cross-sectional shape as the rails


14


of the guardrail


10


(FIG.


1


).




A mounting plate


40


is secured to the forward end of the guide rail


34


, as for example by welding. In this embodiment, the mounting plate


40


is oriented at a skew angle with respect to the longitudinal axis of the guide rail


34


. This is not required in all embodiments, but it provides the advantage that the vehicle-engaging portion


32


may be mounted perpendicular to the anticipated impact direction D (

FIG. 1

) even though the forward end of the guardrail


10


is flared outwardly from the roadway R and is therefore itself not aligned with the anticipated impact direction D.




As best shown in

FIG. 4

, the guide rail


34


also defines an array of nine slots


42


, each extending axially along the guide rail


34


. A tongue


44


is mounted centrally to the guide rail


34


to extend rearwardly of the guide rail


34


. Additionally, a window


56


is formed in the forward portion of the guide rail


34


.




Returning to

FIG. 3

, the vehicle-engaging portion


32


is secured, as for example with threaded fasteners, to the mounting plate


40


via a C-channel


46


. In this embodiment the vehicle-engaging portion


32


itself is welded from angle-iron segments.




As shown in

FIG. 3

, a brace


48


extends between the lower portion of the vehicle-engaging portion


32


and a rearward portion of the guide rail


34


. The front of the brace


48


is bolted with a fastener


50


to the bottom of the vehicle-engaging portion


32


. The rear of the brace


48


is bolted via fasteners


52


and an angle bracket


54


to the valley


38


of the guide rail


34


.




As best shown in

FIG. 2

, the impact-receiving element


30


is secured to the forward end


28


of the front rail


14


by threaded fasteners


58


.

FIG. 8

clarifies the structural relationships. Each of the fasteners


58


passes through a respective opening in the rail


14


and through a respective slot


42


in the guide rail


34


. Spacers


60


ride within the slots


42


and are dimensioned to insure that the fasteners


58


do not clamp the guide rail


34


to the rail


14


so as to immobilize the guide rail


34


.

FIG. 7

is another cross-sectional view that shows the manner in which the angle bracket


54


is mounted to the guide rail


34


in such a way as not to interfere with sliding movement between the rails


14


,


34


.




Returning to

FIG. 2

, the forward end of the forward rail


14


is secured to the first post


18


by a threaded fastener


61


in the conventional manner. The window


56


ensures that the fastener


61


does not clamp the guide rail


34


to the first post


18


and thereby immobilize it.




A column


62


is mounted between the vehicle-engaging portion


32


and the first post


18


. In this embodiment, the column


62


comprises a section of angle iron that is bolted to a strap that is in turn bolted in place between the post


18


and the vehicle-engaging portion


32


.




Preferably the forward end of the first rail


14


is also secured to the first post


18


by a cable


64


. This cable


64


is secured to the rail


14


at its rearward end by a conventional mounting bracket


66


, and the cable


64


is secured at its forward end to the first post


18


. Preferably, the mounting of the cable


64


to the rail


14


and the post


18


readily releases the cable


64


from the post


18


when the post


18


is broken in an axial impact, as described in U.S. patent application Ser. No. 08/990,468 filed Dec. 15,1997, assigned to the assignee of the present invention. The entirety of this related specification is hereby incorporated by reference.





FIGS. 9 through 11

show perspective views of the posts


18


,


20


,


16


, respectively. The first and second posts


18


,


20


are weakened with bores


68


, and the first post


18


is additionally weakened by saw kerfs


70


. The post


16


of

FIG. 11

(which is used for posts


3


-


10


of the guardrail


10


) is weakened by through bores


72


.




Simply by way of example, the following additional structural details are provided to define the best mode of this invention. These details are intended only by way of illustration, and should clearly be understood to be preferred only. None of these details should be used to limit the scope of the following claims.




By way of example, the rails


34


,


14


may be formed of 12 gauge sheet metal shaped as defined in AASHTO specification M80-89 Class A, Type III. These rails may be hot-dip galvanized (Type II-zinc coated). A 2-inch upset positioned along a line perpendicular to the length of the rail completely across the rail may be formed in the first rail


14


approximately 15 centimeters in front of the center line of post


3


. The vertical cross-section of the rail at the center of the upset can be shaped as shown in

FIG. 12

, in which the cross-section at the center of the upset or crimp is shown in solid lines and the uncrimped section is shown in dotted lines. The central valley is deformed by a maximum of 14 mm and the lateral edges are deformed by a maximum of 32 mm in this example. Similar upsets can be formed in the second and third rails


14


aligned with the center lines of posts


5


and


9


, respectively. These upsets provide preferred bending positions for the array of rails


14


without reducing tensional strength excessively. In order to achieve the desired folding in an axial impact, the rails


14


are bolted to posts


1


,


5


and


11


, and to all remaining posts downstream of post


11


. In this way, the posts provide backup to the array of rails


14


against an oblique impact, while the rails are left free to collapse away from selected ones of the posts in an axial impact.




The vehicle-engaging portion


32


can be fabricated of ¼-inch thick steel angles. The posts


18


,


20


can be formed of wood (S4S min. grade 8 MPa) with a cross-sectional dimensions of 190×140 mm and a length of 1086 mm. The bores


68


can be 60 mm in diameter. The post


16


of

FIG. 11

can be formed of wood, having cross-sectional dimensions of 203×152 mm and a length of 1830 mm. The bores


72


can be 63.5 mm in diameter. Preferably each post


16


is formed of select structural grade timber for 300 mm on either side of the bores


72


. The remainder of each post can be #2 grade timber.




As assembled, the impact-receiving element


30


is slidably attached with low friction to the forward end of the forward guardrail


14


, and the column


62


insures that compressive loads applied to the vehicle-engaging portion


32


are transmitted to an upper portion of the first post


18


. In this embodiment, the slots


42


are 157 mm in length, and thus the limited stroke provided to the impact-receiving elements


30


is approximately 136 mm. In an axial impact, a vehicle traveling in the anticipated impact direction D first contacts a vehicle-engaging portion


32


. As the vehicle pushes the vehicleengaging portion


32


rearwardly, the column


62


transfers compressive loads to the first post


18


, thereby fracturing the first post


18


in the region of attachment of the cable


64


. Once the first post


18


is broken, the cable attachment releases the cable


64


from the first post


18


. This reduces the impact force required to buckle the rails


14


, and thereby reduces decelerating forces applied to the impacting vehicle by the guardrail


10


.




Continued rearward motion of the vehicle-engaging portion


32


and the guide rail


34


causes the tongue


44


to fit within the mating element


66


to immobilize the rearward end of the guide rail


34


. This laterally reinforces the forward end of the first rail, because the guide rail


34


is at this point secured to the first rail


14


at both ends. This lateral reinforcement reduces the tendency of the rail


14


to buckle near the impacting vehicle and increases the tendency of the rail


14


to buckle away from post


3


at the first crimp. When the fasteners


58


reach the forward ends of the slots


42


, further rearward motion of the impact-receiving element


30


causes rearward motion of the front end of the first rail


14


. Note that the forward end of the brace


48


(

FIG. 2

) protrudes forwardly of the vehicle-engaging portion


32


. This protrusion is designed to engage the impacting vehicle (not shown) in the region of the bumper or below, thereby resisting any tendency of the front end of the guardrail


10


to rise in an impact.




It should be apparent from the drawings that the frontal area A1 of the vehicle-engaging portion


32


(

FIG. 2

) is substantially larger than the frontal area A2 of the front face of one of the rails


14


. In this example, the frontal area A1 is about 2100 cm


2


(457 mm×457 mm), and the frontal area A2 is about 13.3 cm


2


(494 mm×2.7 mm). The ratio A1:A2 is therefore approximately 157:1. The frontal area A1 is defined by the outer perimeter of the vehicle-engaging portion


32


, regardless of whether or not there are internal openings in the vehicle-engaging portion


32


.




Because the frontal area of the vehicle-engaging portion


32


is so large, there is a minimal tendency for the guardrail


10


to impale an impacting vehicle. Furthermore, since the impact-receiving element


30


is slidably mounted on the forward rail


14


, initial deceleration spikes experienced by a lightweight impacting vehicle are reduced. Deceleration forces on the vehicle are applied in a direct manner to the forward post in order to minimize deceleration spikes at the beginning of the impact.




Of course, it should be understood that many changes and modifications can be made to the preferred embodiment described above. For example, the vehicle-engaging portion


32


can be shaped otherwise and formed of other materials. The ratio A1:A2 is preferably greater than 50:1, more preferably greater than 100:1, and most preferably greater than 150:1. If desired, a retroreflective material can be placed on or in the vehicle-engaging portion


32


. The column


62


can be formed and shaped as desired, and in some embodiments may be formed of wood or other materials. The separate brace


48


is not required in all embodiments, and it is not required that the brace


48


protrude forwardly of the vehicle-engaging portion


32


. If desired, the slots


42


can be formed in the first rail


14


, or slots may be provided in both the rail


14


and the guide rail


34


. Many other configurations are possible for the guide rail


34


and the rail


14


, including corrugated rails having two or more valleys separated by parallel ridges.




As used herein, terms that appear in the following claims are intended broadly. For example, an array of elements is intended broadly to encompass one or more such elements.




The term “end” is intended broadly to encompass regions at and near the extreme end of an element.




The term “post” is intended broadly to encompass posts made of timber, metal or other materials.




The term “impact-receiving” indicates that the associated element receives at least some of the impacts on the guardrail. As explained above, oblique impacts to the intermediate portion of the guardrail may not contact the impact-receiving element.




Similarly, the term “anticipated impact direction” indicates one of several anticipated impact directions, in this case in a direction aligned with or at a small angle with respect to the longitudinal axis of the guardrail.




The term “slideably” is intended broadly to encompass relative translational movement of two overlapping elements, with or without restraints such as friction or deformation.




The term “roadway” is intended broadly to encompass any travel lane for vehicular traffic, including highways, tracks, trails and racecourses.




The term “skew” is intended broadly such that two elements are at skew angles at any time that they are neither parallel nor perpendicular to one another.




The foregoing detailed description has described only a few of the many forms that this invention can take. For this reason, this detailed description is intended as illustrative and not as limiting. It is only the following claims, including all equivalents, that are intended to define the scope of this invention.



Claims
  • 1. In a guardrail comprising an array of vehicle-deflecting rails secured to an array of posts extending along a roadway, said array of rails comprising a first rail having a first end, said array of posts comprising a first post at the first end of the first rail, the improvement comprising:an impact-receiving element slidably mounted to the first end of the first rail; a stop coupled to at least one of the impact-receiving element and the first rail to limit sliding movement of the impact-receiving element relative to the first rail; said impact-receiving element comprising a vehicle-engaging portion having a first frontal area A1, said first end of the first rail having a second frontal area A2, said first frontal area A1 being substantially greater than said second frontal area A2; said impact-receiving element coupled with the first post such that impact forces on the vehicle-engaging portion are applied to the first post to break the first post before the stop limits sliding movement of the impact-receiving element relative to the first rail.
  • 2. The invention of claim 1 wherein the impact-receiving element extends forwardly of the first post in an anticipated impact direction.
  • 3. The invention of claim 2 further comprising a column interposed between the first post and the vehicle-engaging portion.
  • 4. The invention of claim 2 wherein the impact-receiving element comprises a guide rail secured to the first rail.
  • 5. The invention of claim 4 wherein at least one of the guide rail and the first rail comprises an array of slots, and wherein the guide rail is secured to the first rail by a plurality of fasteners that pass through the slots such that the slots and the fasteners form a guide that allows sliding motion between the first rail and the guide rail over a limited stroke.
  • 6. The invention of claim 5 further comprising a brace secured between the guide rail and the vehicle-engaging portion.
  • 7. The invention of claim 6 wherein the vehicle-engaging portion comprises a frame.
  • 8. The invention of claim 5 further comprising a column secured between the first post and the vehicle-engaging portion.
  • 9. The invention of claim 1 wherein the ratio A1:A2 is no less than about 100:1.
  • 10. The invention of claim 1 wherein the ration A1:A2 is no less than about 150:1.
  • 11. The invention of claim 1 wherein the vehicle-engaging portion is oriented at a skew angle with respect to the first rail.
  • 12. The invention of claim 1 wherein the first post is disposed forwardly of all other posts of the guardrail in an anticipated impact direction.
  • 13. The invention of claim 12 wherein the impact-receiving element is slideably mounted relative to the first post.
  • 14. The invention of claim 1 wherein the ratio A1:A2 is no less than about 50:1.
  • 15. The invention of claim 1 wherein the stop comprises a rearwardly protruding tongue positioned to engage a mating element on the first rail when the impact-receiving element is moved rearwardly in an impact.
  • 16. The invention of claim 1 wherein the array of posts comprises a forwardmost post and an adjacent post in an anticipated impact direction, and wherein the stop is positioned between the forwardmost post and the adjacent post.
  • 17. The invention of claim 1 wherein the first post is the forwardmost post in an anticipated impact direction, wherein the array of posts comprises a second post rearwardly adjacent to the first post, and wherein the stop is positioned forwardly of the second post in the anticipated impact direction.
  • 18. The invention of claim 1 wherein the impact-receiving element is supported entirely by the first rail.
  • 19. The invention of claim 1 further comprising a cable anchored at a forward end to the first post and at a rearward end to the first rail, wherein the first post is the forwardmost post of the array of posts in an anticipated impact direction.
  • 20. The invention of claim 1 wherein the impact-receiving element is slideably mounted on the first rail relative to the first post.
  • 21. In a guardrail comprising an array of vehicle-deflecting rails secured to an array of posts extending along a roadway, said array of rails comprising a first rail having a first end, said array of posts comprising a first post at the first end of the first rail, the improvement comprising:an impact-receiving element slidably mounted to the first end of the first rail; said impact-receiving element comprising a vehicle-engaging portion having a first frontal area A1, said first end of the first rail having a second frontal area A2, the ratio A1:A2 being no less than about 50:1; wherein the impact-receiving element extends forwardly of the first post in an anticipated impact direction; wherein the impact-receiving element comprises a guide rail secured to the first rail; wherein at least one of the guide rail and the first rail comprises an array of slots; and wherein the guide rail is secured to the first rail by a plurality of fasteners that pass through the slots such that the slots and the fasteners form a guide that allows sliding motion between the first rail and the guide rail over a limited stroke; further comprising a brace secured between the guide rail and the vehicle-engaging portion; wherein the brace protrudes forwardly of the vehicle-engaging portion.
  • 22. In a guardrail comprising an array of vehicle-deflecting rails secured to an array of posts extending along a roadway, said array of rails comprising a first rail having a first end, said array of posts comprising a first post at the first end of the first rail, the improvement comprising:an impact-receiving element slidably mounted to the first end of the first rail; said impact-receiving element comprising a vehicle-engaging portion having a first frontal area A1, said first end of the first rail having a second frontal area A2, the ratio A1:A2 being no less than about 50:1; wherein the impact-receiving element extends forwardly of the first post in an anticipated impact direction; wherein the impact-receiving element comprises a guide rail secured to the first rail; wherein the guide rail comprises a rearwardly protruding tongue positioned to engage a mating element on the first rail when the guide rail is moved rearwardly in an impact.
  • 23. In a guardrail comprising an array of vehicle-deflecting rails secured to an array of posts extending along a roadway, said array of rails comprising a first rail having a first end, said array of posts comprising a first post at the first end of the first rail, the improvement comprising:an impact-receiving element slidably mounted to the first end of the first rail; said impact-receiving element comprising a vehicle-engaging portion having a first frontal area A1, said first end of the first rail having a second frontal area A2, the ratio A1:A2 being no less than about 50:1; wherein the impact-receiving element extends forwardly of the first post in an anticipated impact direction; wherein the impact-receiving element comprises a guide rail secured to the first rail; wherein at least one of the guide rail and the first rail comprises an array of slots; wherein the guide rail is secured to the first rail by a plurality of fasteners that pass through the slots such that the slots and the fasteners form a guide that allows sliding motion between the first rail and the guide rail over a limited stroke; further comprising a column secured between the first post and the vehicle-engaging portion; wherein the column is dimensioned such that impact forces on the vehicle-engaging portion are applied to the first post to break the first post before the guide rail completes the stroke.
  • 24. In a guardrail comprising an array of vehicle-deflecting rails secured to an array of posts extending along a roadway, said array of rails comprising a first rail having a first end, said array of posts comprising a first post at the first end of the first rail, the improvement comprising:an impact-receiving element slidably mounted to the first end of the first rail; said impact-receiving element comprising a vehicle-engaging portion having a first frontal area A1, said first end of the first rail having a second frontal area A2, said first frontal area A1 being substantially greater than said second frontal area A2; said impact-receiving element coupled with the first post such that impact forces on the vehicle-engaging portion are applied to the first post; said impact-receiving element slideably mounted on the first rail, and said impact-receiving element being free of attachment to the first post when in an initial condition, prior to application of said impact forces.
  • 25. The invention of claim 24 wherein the impact-receiving element is supported substantially entirely by the first rail.
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4678166 Bronstad et al. Jul 1987
4928928 Buth et al. May 1990
5022782 Gertz et al. Jun 1991
5078366 Sicking et al. Jan 1992
5391016 Ivey et al. Feb 1995
5407298 Sicking Apr 1995
5503495 Mak Apr 1996
5547309 Sicking Aug 1996
5775675 Sicking et al. Jul 1998
5791812 Ivey Aug 1998
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5957435 Bronstad Sep 1999
5967497 Denman et al. Oct 1999
6022003 Sicking et al. Feb 2000