[0001] This invention relates to roadway markers or guide posts. More particularly, it is
concerned with resilient posts which permit nondestructive deformation upon impact
by a moving object.
[0002] Vehicle traffic control requires the use or road signs and markers as aids in solving
the various problems associated with traffic safety and direction. It has been found
that a useful characteristic for such signs and markers is that these posts have the
ability to withstand vehicle impact, without requiring subsequent replacement. An
attempt has been made to fill this need with various configurations of posts. However,
the structural design of such posts has involved the consideration of two opposing
structural features, i.e. the elasticity required during dynamic conditions to permit
the post to nondestructively bend with vehicle impact and the longitudinal rigidity
required during static conditions to withstand forces resulting as the post is driven
into a hard surface.
[0003] The elasticity is necessary in view of frequent high speeds associated with impacts
between a moving vehicle and stationary post. In such cases, if the post could not
bend it would likely shear off, and would have to be replaced. Mere bendability, however,
is not sufficient, since each time a post was bent it would have to be straightened
before it could again be functional. This could involve high maintenance costs. Ideally,
a post should also have sufficient elasticity that it will automatically assume its
proper upright configuration after dissipation of any impact forces.
[0004] While elasticity is desirable, the elasticity may present a practical problem when
installation of the post is considered. In the past, when deformable plastics have
been used as post material, installation has frequently required predrilling a hole
or insertion of some support receptacle into the ground, with the subsequent positioning
of the plastic post into the hole or receptacle. These preliminary steps were required
because such previously known elastic posts would not withstand a buckling force applied
during attempts to drive the posts into hard surfaces. Consequently, the same elastic
properties which permitted the nondestructive deformation upon impact caused the buckling
of a post subjected to a driving force along its axis.
[0005] Attempts have been made to incorporate the dual requirements of elasticity and rigidity
by utilizing a spring within an otherwise rigid post, and with the rigid parts of
the post being secured on opposite ends of the apring. Installation was by compressing
the spring and then pounding along the now rigid longitudinal axis. After installation,
the deformable character of the post was accomplished by the transverse elastic property
of the included spring.
[0006] This configuration, however, has several apparent disadvantages. The rigid portion
of the structure has customarily been made of strong materials which may dent or otherwise
damage the impacting vehicle. Furthermore, the use of such rigid materials and springs
and the assembly requirements result in excessive costs for the posts.
[0007] U.S. Patent No. 3,875,720 discloses a second approach to the problem, of providing
elasticity in a post that can be driven. In this patent a post is formed by a bundle
of flexible rods that are clamped together to obtain the desired rigid property required
during the static installation stage of the post. Deformation of the post during dynamic
conditions is permitted by deflection of the various flexible rods away from the central
axis of the post structure. Here again, however, economic factors appear to have impeded
utilization of such structure despite the growing need for such a post.
[0008] It is therefore an object of the present invention to provide a deformable post configuration
having both longitudinal rigidity and bending elasticity to facilitate driving emplacement
and subsequent impact without destructive deformation.
[0009] It is a further object of the present invention to obtain this dual character by
utilization of a geometrical configuration adapted to minimize bending stress while
at the same time retaining the high modulus of elasticity necessary to preserve longitudinal
rigidity.
[0010] An additional object of the present invention is to accomplish the afore-mentioned
dual character by means of reinforcing a web structure with a suitable arrangement
of fibers.
[0011] A still further object of this invention is to develop the desired dual character
of elasticity and rigidity by incorporating reinforcing rib structure longitudinally
along the post structure.
[0012] It is yet another object of the present invention to provide a post structure having
transverse flexibility to permit lateral contortion and/or deformation to a minimal
thickness and thereby reduce moment of inertia and bending stress.
[0013] It is also an object of this invention to provide means for protecting attached marker
materials from impact and weather degradation.
[0014] These and other objects of the present invention are realized in a post configuration
(hereinafter referred to as a delineator) wherein the delineator comprises an elongated
web and associated reinforcing structure. The web portion of the delineator provides
the flexible properties which permit bending of the delineator in response to a bending
impact force. The reinforcing structure is necessary to develop a high modulus of
elasticity along the longitudinal axis of the delineator. Such reinforcing structure
is implemented by specific utilization of fiber orientation within the web structure
or by configuring the structure geometrically to provide ribs having the desired high
modulus of elasticity which will complement the bending properties of the web structure.
Other objects and features will be obvious to a person of ordinary skill in the art
from the following detailed description, taken with the accompanying drawings.
[0015] In the drawings:
Figure 1 is a fragmentary perspective view of a delineator of the present invention,
having a partially cut away section.
Figure 2 is a perspective view of the delineator in combination with a roadway.
Figure 3 is a fragmentary, partially cut away view of a second embodiment of the present
invention.
Figure 3a shows an enlarged, fragmentary view taken within the line 3a-3a of Figure
3.
Figure 4 depicts a fragmentary perspective view of an additional embodiment of the
present invention.
Figure 4a shows an enlarged, fragmentary view taken within the line 4a-4a of Figure
4.
Figure 5 is a perspective view of a delineator immediately after impact with a moving
object.
Figure 6a is a horizontal cross-section view, taken on the line 6a of Figure 5.
Figure 6b is a horizontal cross-section view, taken along the line 6b of Figure 5.
Figure 7 shows a fragmentary view of an additional embodiment of the present invention.
Figure 8 shows a fragmentary view of a delineator enclosed by a rigid-body casing,
shown in perspective.
Figure 9 depicts a protective cap for use with the subject delineator.
[0016] Referring now to the drawings:
[0017] The present invention relates to the establishment of proper elastic and rigid mechanical
properties within a delineator structure. The normal use of such a roadway delineator
entails two separate forms of stress application. Initially, the delineator is subjected
to installation stress as the delineator is driven into a hard surface, such as ground.
Typically, this driving force is applied to the top end of the delineator and therefore
represents a longitudinal force extending down the length of the delineator. It is
noted that this stress arises when the delineator is in a static state, i.e. when
no bending forces are being applied. The required mechanical properties necessary
to avoid buckling of the delineator under the applied driving load, are represented
in the following formula:
[0018] Where: E=elastic modulus in compression I=moment of inertia L=length of the column
P
E=maximum buckling load
[0019] Once the length L of the delineator is established the product of EI becomes determinative
of the ultimate buckling load the post can withstand.
[0020] A second form of stress anticipated for the delineator is the bending stress applied
upon impact by a moving object with a surface of the delineator. This form of stress,
arising during dynamic conditions, is represented by the following relationship:
[0021] Where: f
b=bending stress M=bending moment C=distance from neutral axis to point of stress
[0022] Bending moment M is defined by the expression:
[0023] Where: E = elastic modulus I = moment of inertia R = radius of curvature
[0024] In dealing with both forms of stress, therefore, it is imperative that the proper
relationship be established between the elastic modulus E and the moment of inertia
I.
[0025] From the equations defining the respective forms of stress applied to the delineator,
it is apparent that rigid posts, such as those made of metal or wood, have a very
high buckling load factor, PE. With such materials both E and I may have very large
values. This factor is favorable during installation, but may be catastrophic upon
vehicle impact.
[0026] This adverse condition is apparent from equation (3), which may be rewritten in the
form
In this case it is apparent that the large product of EI from the previous buckling
formula (1) would result in a large radius of curvature R which is clearly adverse
to applications for delineators to be subject to impact deformation. Customarily,
such impact will usually involve a motor vehicle whose structure will require the
delineator to deform to a radius of a curvature of approximately 18 inches (45.72
em). Where the product of EI is high and the point of impact is approximately 18 inches
(45.72 cm) above ground level (making M quite low in value) the resultant radius of
curvature is far too large and the motor vehicle may simply shear off the delineator
between the point of impact and ground level.
[0027] An important aspect of the present invention is the recognition that, under typical
uses of a delineator, the value of EI in the static condition during installation
will not satisfy the bending requirements experienced during impact at a lateral surface.
Inherent properties within the delineator are required which will develop a lower
EI product during dynamic bending. Simply stated, the most versatile delineator must
respond to a driving load with a high EI product to preclude buckling, but must experience
a lower EI during bending subsequent to impact.
[0028] The present invention involves unique structural design to establish a proper balance
between E, the elastic modulus and I, the moment of inertia. Whereas large values
of E are required to maintain the necessary rigidity to withstand the longitudinal
driving force arising dvring static conditions of installation, I is of minimal value
to improve the bending ability of the delineator to achieve a low radius of curvature.
The delineator of the present invention provides a variable EI response to the respective
loading and bending stresses, to satisfy both static and dynamic conditions in a single
embodiment.
[0029] Figure 1 illustrates one embodiment of the delineator utilizing concepts of the subject
invention, wherein the appropriate balance between E and I is obtained by a combination
of geometrical structure and material composition. The delineator, shown generally
as 10, is constructed of a plastic binder with reinforcing fibers. The plastic binder
may be any suitable plastic which is capable of withstanding the variations of temperature
to which it will be subjected and which possesses the desired elongation characteristics
to prevent massive fracturing upon impact.
[0030] Thermosetting resin material is particularly well suited for this application in
as much as it is not dependent upon temperature to maintain its flexibility. To the
contrary, many thermoplastic materials become too brittle when exposed to subfreezing
temperatures and result in massive fractures upon impact with a moving vehicle. Where
the thermoplastic resin is capable of withstanding temperature variation without concurrent
hardening, however, such material may well be suited as binder material for the subject
invention.
[0031] In order to establish the necessary rigidity to the delineator body 10, reinforcing
fiber is embedded within the binder material. A portion 17 of this fiber is positioned
longitudinally along the length of the delineator structure. For extra longitudinal
strength, a high modulus fiber such as "KEVLAR" may be used. A second layer 16 of
fiber material is oriented in random direction to establish tensile strength and to
contribute to the proper balance between rigidity and flexibility. A surface coating
15 is utilized to protect the contained binder/fiber combination from weather, ultraviolet
rays and other adverse effects of the environment. In addition to the suggested form
of Figure 1, the arrangement of longitudinal versus random fibers within the structure
may be varied such that the random fiber may form a core, with the longitudinal fiber
comprising the second layer thereon.
[0032] It has been determined that at least seven percent by weight but no more than sixty
percent of the fiber arrangement be in random orientation. The remaining amount of
fiber is longitudinally oriented to establish the rigidity required for driving the
delineator into the ground. Furthermore, although random fiber orientation is described
and is shown in Figure 1, similar transverse flexibility and tensile strength properties
can be established where fiber orientation is directed at various predetermined transverse
angles of orientation, such as is best shown at 36 in Fig. 3.
[0033] It has also been found that where the binder material comprises twenty to forty percent
by weight of the delineator structure, use of more than sixty percent random fiber
adversely affects the elastic character which is required to restore the delineator
to its original position after impact. Also, failure to use at least forty percent
of the fiber in the longitudinal orientation, without other reinforcing structure,
will result in insufficient resilience or elastic modulus to permit the delineator
to be driven into the ground. This use of proper amounts of fiber coordinated between
transverse and longitudinal orientations, represents an effective method of establishing
the appropriate E and I within the delineator structure.
[0034] A second method for establishing sufficient elastic modulus while preserving resistance
to a buckling load is accomplished through geometrical configurations such as shown
for examples by the rib structures 11 and 13 in Figure 1. In utilizing reinforcing
ribs to obtain the higher elastic modulus desired, it is important that such rib structure
not extend a substantial distance away from delineator surfaces 14 and 18, since bending
stresses arising therein during curvature of the delineator will result in longitudinal
shearing along the junction of the rib and web portion 12 of the delineator body.
The effect of slightly protruding rib structure, however, is to extend the apparent
thickness of the delineator and thereby increase the moment of inertia 1, without
subjecting the rib structure to excessive stress during the dynamic bending phase.
By reinforcing such rib structures 11 and 13 with longitudinal fiber, 17, the elastic
modulus E is also increased resulting in even greater rigidity, without increasing
rib thickness.
[0035] In circumstances where less buckling stress is anticipated with respect to installation
of delineator, rib structure may be omitted and both E and I can be satisfied by the
use of proper orientations of reinforcing fibers in combination with a nonplanar (i.e.
concave) web structure such as is illustrated by the delineator structure 70 in Figure
7. Such a slightly concave delineator body, reinforced with longitudinal fibers, can
withstand a limited driving load imposed at the top thereof while retaining sufficient
flexibility to bend without destructive deformation.
[0036] A second configuration is illustrated in Figure 3 and 3a, in which a single rib 31
supplys the reinforcing strength to permit driving of the delineator into the hard
surface. In this case, the reinforcing rib 31 is located on a nonimpacting surface
34 of the delineator 30. The thickness of the web portion 32 will depend upon the
anticipated impact force associated with the delineator environment. As with previous
examples, the full web with reinforcing rib structure may be fully reinforced with
the appropriate combination of transverse and longitudinal fibers 36 and 37.
[0037] With the single reinforcing rib 31, a somewhat larger rib thickness might be desired
to increase moment of inertia and longitudinal rigidity. Although this larger rib
size will improve drivability, excessive size will reduce the desired flexibility
required for withstanding bending stress. This reduction in flexibility may be partially
alleviated by reducing longitudinal fiber content in the rib body and slightly inceasing
the transverse fiber arrangement to develop a minor fracture capability upon the initial
impact of a bending force with the delineator. With this characteristic construction
the delineator, prior to bending impact, has increased longitudinal rigidity to withstand
the anticipated driving force to be applied during installation. After installation,
however, a reduction of moment of inertia and improved flexibility to withstand bending
stress is achieved upon an initial impact which develops transverse fractures 33 along
the rib length.
[0038] When such impact occurs at the front surface 38, the delineator structure curves
rearward, causing compression on the back surface 34 and reinforcing rib 31. Because
of the shorter radius of curvature imposed upon rib 31, increased compression occurs
lorgitudinally along the rib structure and with the reduced longitudinal fiber, minor
transverse fracturing occurs 33. Total shearing or destruction of rib 31 is avoided
by means of sufficient longitudinal and random fiber content within the rib portion,
with random fiber arrangements being interconnected and intermingling with the attached
web structure. The end result, therefore, is a rib reinforcement having small, multiple
transverse cracks along its length to facilitate subsequent compliance to bending
stress. At the same time, however, some stabilizing influence remains by reason of
some surviving continuity of the rib structure.
[0039] An additional method of developing high EI for drivability, but lower EI during bending
movements is to incorporate a network of microspherical voids within the delineator
structure. This concept is illustrated in Figure 4a. Such voids 45 can be introduced
during fabrication by conventional techniques and will operate to lower the movement
of inertia and thereby enhance flexibility. Furthermore, although longitudinal rigidity
will be retained due to static strength inherent in this configuration, a violent
lateral impact will cause the microspheres to partially collapse and operate as tiny
hinges to facilitate bending movement.
[0040] As shown best in Figure 4, other geometrical configurations can be used to establish
a balance between E and I. The particular configuration shown in Figure 4 utilizes
structural thickness to develop the increased elastic modulus required to obtain drivability
for the delineator 40. By utilizing rib structures 43 at the edges of the web structure
42 and a thicker central portion of web structure 41, an increased effective thickness
is obtained to satisfy ultimate buckling load requirements. Such effective thickness
extends from the front contacting edges of the forward extending ribs 43 through the
rearward ridge of the central reinforcing rib 41.
[0041] This effective thickness, of course, represents the static condition of the structure
of the delineator. On impact, bending forces cause the contortion of the outer ridges
43 in angular rearward movement. This structural deformation facilitates improved
bending because of the concurrent reduction of apparent thickness of the delineator
body and moment of inertia. Such structure directly implements the concept of variable
EI product in response to static and dynamic conditions. In Figure 5, the deformed
delineator 50 is shown immediately after impact with an automobile 58. The elastic
forces of the delineator are in the process of restoring the upper portion 59 of the
delineator to its original upright position. Figure 6b illustrates the unflexed, apparent
thickness of the delineator viewed at the cross section view taken along line 6b.
Here the hard ground structure forces the delineator to retain its static configuration,
having an apparent thickness extending from i to iv. It is this extended thickness
dt which strengthens longitudinal rigidity in the otherwise thinned web structure
between ii and iii, and provides the higher EI for this condition.
[0042] Such configuration is modified, however, during contortions illustrated in Figure
5, as represented in the Figure 6a view. The thinner structure of the web body 62
permits greater flexibility and causes rotation of the more massive ridge members
63 in angular rotation rearward. The effect of such contortion is to reduce the thickness
of the delineator from its static thickness of dt in Figure 6b to a reduced thickness
di of Figure 6a. The relationship defined by Equation (2)
shows that any reduction in thickness causes a decrease in the value of C, the distance
from the neutral axis to the point of stress. This factor assists in satisfying the
requirement for reduced moment of inertia, or increased flexibility, to avoid destructive
deformation of the delineator. This characteristic of lateral angular contortion is
developed where reinforcing rib structure, having less flexibility than the attached
web structure in the transverse direction, is subjected to such a bending impact force.
[0043] In addition to the application of this principle to planar type web structures such
as illustrated in Figures 1, 2, 3, 4, and 5, nonplanar web structures are likewise
adaptable to a proper balance of rigidity and elasticity. Figure 7 illustrates one
such embodiment, having lateral edges 72 that are comprised of thermosetting resins
which may be reinforced with appropriate fibers in the transverse and longitudinal
directions and a central portion 73 containing a longitudinal section of thermoplastic
material 74 having greater flexibility than the attached thermosetting material section.
As with the prior example, impact at a frontal surface 78 causes rearward angular
contortion at the lateral edges 72 which effectively reduces the overall thickness
of the delineator, thereby improving its bendable character. The elastic properties
of both materials operate to restore the concave structure upon removal of the impacting
force. With the combination of concave structure for improved longitudinal rigidity
and the improved transverse flexibility of the central section 73, this configuration
is also satisfactory in so far as both elasticity and rigidity are concerned.
[0044] A common feature of each embodiment described is that a unibody construction exists
which incorporates the intermingling of fibers or other supporting rib structure with
a web portion having a more flexible character. During installation procedures the
higher EI is realized in the reinforced sections of the delineator which operate as
the primary load bearing element. Such occurs, for example, at the central ridges,
distal ribs, or any areas of greater thickness. During bending contortions following
impact, however, the angular contortion of the more flexible web portion of the structure
provides a reduced moment of inertia and therefore a reduced stress due to the decreased
distance between the neutral axis and the various points of stress along the delineator
body.
[0045] More specifically, the subject delineator includes a web structure having a tapered
base to facilitate insertion thereof into a hard surface and is constructed of a material
composition which develops a modulus of elasticity (E) sufficiently high, when taken
in combin
- ation with the moment of inertia (I) of said web structure, to withstand a longitudinal
impact force having values up to a maximum buckling load (
PE) in accordance with a delineator length parameter (L) as defined by the relation
FE = 2 EI said impact force
L2 being applied near the top of a longitudinal axis of said delineator during static
installation conditions; said product of EI being variable in response to deformation
of saiddelineator by a lateral impact force which modifies said geometric structure
to decrease the moment of inertia (I) and develop a delineator bending radius (R)
as defined by the relationship R = EI , M wherein M is the bending moment of said
delineator, said bending radius being sufficiently low to permit passage of a vehicle
over said delineator, said material composition having sufficient elasticity to restore
to its upright orientation upon dissipation of said impact force; said geometric structure
comprising a nonplanar impacting surface of said web structure which responds with
angular contortion upon occurrence of said lateral impact, thereby decreasing the
moment of inertia of said delineator during bending motion, reducing said EI product
from a longitudinal rigid structure to a flexible structure during deformation.
[0046] With respect to delineators manufactured with a plastic binder and reinforcing fibers,
the subject delineator comprises an elongate web having concurrent characteristics
of a sufficiently high modulus of elasticity for withstanding buckling loads applied
during static conditions along its longitudinal axis during installation and a sufficiently
low moment of inertia to establish elastic character in an exposed section of said
delineator to permit nondestructive deformation upon impact by a moving object and
subsequent immediate restoration to an original, upright orientation, said elongate
web structure comprising a combination of random (or transverse) and longitudinally
oriented fibers imbedded in 20 to 40% (w) resin binder, said fiber combination being
comprised of at least 7% but not more than 60% fiber in random arrangement to provide
transverse flexibility and tensile strength, and said longitudinal orientation of
fiber comprising the remaining percentage of total fiber content to provide longitudinal
rigidity during said static conditions.
[0047] As best shown in Figure 8 a removable,rigid-body casing 81 may be positioned around
a portion of the delineator structure 80. The effect of this rigid-body casing is
to reduce the length of the delineator exposed to buckling forces during installation
procedures. This reduced length decreases the denominator of equation (1), thereby
increasing the ultimate buckling load. It is noted that since the length parameter
of the referenced equation is squared, any reduction in length greatly magnifies the
increase in buckling load capable of being withstood.
[0048] Typical construction materials used for the rigid-body casing 81 would be steel or
other heavy-duty substances capable of withstanding buckling pressures exerted by
the delineator contained within the casing. Additionally, the casing may be capped
with an impactable substance which serves to disperse the driving force along the
top edge 83 of the delineator body 80. By utilizing such a rigid-body casing, the
strength of the reinforcing rib material required for installation is reduced.
[0049] Naturally, the preferred structure for the rigid casing would have the inner surface
conformed to the outer surface of the delineator body to be enclosed. This would restrain
any lateral movement and essentially eliminate that enclosed section from the total
length of the delineator subject to equation (1).
[0050] The reinforcing rib structure located at the contacting face of the various delineators
illustrated herein may also provide protection for sign materials affixed to the delineator
face. As disclosed in Figure 2, the sign material 21 will generally always be attached
at the impacting surface of the delineator 20. Without protective ridging, the sign
surface would be exposed to scraping or other destructive forces as it contacts the
underside of cars or other impacting objects. The lateral ridges protruding forward
from the contacting surface minimize contact with the actual sign surface attached
thereto. Such protection is especially important with less durable sign surfaces such
as reflective tape.
[0051] In connection with the affixation of sign surfaces to the subject delineators, environmental
protection against weathering effects must also be considered. Mere attachment of
reflective tape, for example, may have limited life expectancy, particularly where
the local environment includes rain with freezing weather.
[0052] As a practical matter, water may locate behind the reflector covering, and upon freezing,
dislodge the material from the delineator surface. For this reason, a small notch
is located along a top edge 22 of the delineator surface. The top edge of the tape
is then recessed into the notch and protected from the weathering conditions which
would otherwise tend to detach the material.
[0053] An additional means of protecting the top reflector edge is to use a protective cap
91 as shown in Figure 9. The top edge 92 of the reflective surface 93 is retained
within the enclosed region of the cap structure. In this configuration, exposure to
rain, snow and other adverse weathering elements are minimized and reflector utility
is preserved.
[0054] A supplemental benefit of the capped configuration is the protection given to the
top edge of the delineator during impact with vehicles. During this impacting contact,
the delineator will strike the underside of the vehicle numerous times in attempting
to restore itself upright. After repeated occurrences, the top edge of the delineator
will tend to fray or otherwise degrade. By using a thermoplastic cap having impact
resilience and resistance to ultraviolet radiation, the top edge is protected from
such abrasion. Typically, such a cap is fitted after placement? of the delineator
90 into the ground, since the installation driving force is preferably applied to
the rigid top edge of the delineator body.
[0055] Although the preferred forms of the invention have been herein described, it is to
be understood that the present disclosure is by way of example and that variations
are possible without departing from the scope of hereinafter claimed subject natter.
1. A delineator comprising an elongate web structure having concurrent characteristics
of a sufficiently high modulus of elasticity for withstanding buckling loads applied
during static conditions along its longitudinal axis during installation and a sufficiently
low moment of inertia to establish elastic character in an exposed section of said
delineator to permit nondestructive deformation upon impact by a moving object and
subsequent immediate restoration to an original, upright orientation, said elongate
web structure comprising a combination of random and longitudinally oriented fibers
imbedded in 20 to 40% (w) resin binder, said fiber combination being comprised of
at least 7% but not more than 60% fiber in random arrangement to provide transverse
flexibility and tensile strength, and said longitudinal orientation of fiber comprising
the remaining percentage of total fiber content to provide longitudinal rigidity during
said static conditions.
2. A delineator as defined in claim 1, wherein said resin is selected from the group
consisting of thermosetting resins, thermoplastic resins having a modulus of elasticity
within a range approximating a modulus of elasticity for said thermosetting resins
and thermo- setting/thermoplastic resin combinations having an overall modulus of
elasticity approximating said thermosetting resin modulus.
3. A delineator as defined in claim 1, further comprising a reinforcing longitudinal
rib for improving resilience to said buckling loads, thereby increasing said modulus
of elasticity to enhance drivability, said reinforcing rib haviag unibody construction
with said web, the combination of web with longitudinal rib having at least 7% by
weight of intermingled, random fiber orientation to preclude longitudinal shearing
of said rib during said impact.
4. A delineator as defined in claim 3, wherein said rib is located along a nonimpacting
surface of said delineator and is adapted by suitable imbedded fiber arrangement to
develop small transverse fractures along a length of said rib during bending impact,
said fractures being operable to improve said elastic character by reducing said moment
of inertia.
5. A delineator as defined in claim 3, wherein said reinforcing rib is located along
an impacting surface of said web to protect an exposed sign configuration affixed
to said impacting surface during object contact with said delineator.
6. A delineator as defined in claim 1, wherein said web structure is laterally contoured
by varying web thickness and relative nonplanar web structure to increase moment of
inertia and rigidity along said longitudinal axis.
7. A delineator as defined in claim 1, further comprising one or more longitudinal
rib sections protruding from a surface of said web for permitting reduced thickness
of nonribbed web sections with concurrent reduction of said moment of inertia, said
rib sections being operable to maintain said longitudinal rigidity.
8. A delineator as defined in claim 1, further comprising a reflective surface affixed
to a surface of said web structure.
9. A delineator as defined in claim 8, wherein said reflective surface comprises reflective
tape, said delineator further comprising a transverse notch indenting from said affixed
surface at a top edge of said tape for providing a recessed point of attachment for
said top edge to minimize weathering effects on said tape.
10. A delineator as defined in claim 1, further comprising a protective cap positioned
over a top edge of said delineator for protecting said edge from destructive contact
with said object during impact.
11. A delineator as defined in claim 10, wherein said cap is adapted to receive and
retain a top edge of an attached sign configuration to minimize weathering effects
thereon.
12. A delineator as defined in claim 1, further comprising a removable rigid-body
casing for enclosing a portion of said delineator during installation, said casing
having sufficient inner surface conformity with said delineator to restrain bending
movement of said portion when said driving load is applied.
13. A delineator as defined in claim 12, wherein said casing further comprises an
impactable cap for receiving said driving force and for retaining said casing at an
upper portion of said delineator.
14. A delineator as defined in claim 1, wherein said web structure is laterally contoured
with relative nonplanar web structure to increase moment of inertia and rigidity along
said longitudinal axis.
15. A delineator as defined in claim 14, wherein said nonplanar web includes a first
longitudinal section of thermosetting resin attached to a second longitudinal section
of thermoplastic resin, said first section providing higher elastic modulus for drivability
and said second section providing a low moment of inertia and improved transverse
flexibility to obtain lateral angular contortion of said delineator during bending
to cause a reduction in moment of inertia.
16. A delineator as defined in claim 15, wherein said nonplanar web is concave in
structure having lateral longitudinal sections of thermosetting resin and a central
longitudinal section of thermoplastic resin.
17. A delineator as defined in claim 16, further comprising a network of microspherical
voids within said web structure to reduce moment of inertia and provide differentiating
response to a static, longitudinal load and a dynamic bending force.
18. A delineator as defined in claim 17, wherein said web structure is concavo-convex
at the forward and rearward faces thereof.
19. A delineator as defined in claim 18, further comprising longitudinal rib structure
at side edges of said web structure, said rib structure adding additional longitudinal
rigidity to withstand said buckling loads occurring during installation of said delineator.
20. A delineator comprising an elongate web structure having concurrent characteristics
of a sufficiently high modulus of elasticity for withstanding buckling loads applied
during static conditions along its longitudinal axis during installation and a sufficiently
low moment of inertia to establish elastic character in an exposed section of said
delineator to permit nondestructive deformation upon impact by a moving object and
subsequent immediate restoration to an original, upright orientation, said elongate
web structure comprising a combination of traversing and longitudinally oriented fibers
imbedded in 20 to 40 % (w) resin binder, said fiber combination being comprised of
at least 7% but not more than 60% fiber in traversing arrangement to provide transverse
flexibility and tensile strength, and said longitudinal orientation of fiber comprising
the remaining percentage of total fiber content to provide longitudinal rigidity during
said static conditions.
21. A delineator including:
a web structure having a tapered base to facilitate insertion thereof into a hard
surface and being constructed of a material composition which develops a modulus of
elasticity (E) sufficiently high, when taken in combination with the moment of inertia
(I) of said web structure, to withstand a longitudinal impact force having values
up to a maximum buckling load (PE) in accordance with a delineator length parameter (L) as defined by the relation
PE = π2 EI, EI , L2 said impact force being applied near the top of a longitudinal axis of said delineator
during static installation conditions at said hard surface;
said product of EI being variable in response to deformation of said delineator by
a lateral impact force which modifies said geometric structure to decrease the moment
of inertia (I) and develop a delineator bending radius (R) as defined by the relationship
R = EI, wherein M is the bending moment of said delineator, said bending radius being
sufficiently low to permit passage of a vehicle over said delineator, said material
composition having sufficient elasticity to restore to its upright orientation upon
dissipation of said impact force;
said geometric structure comprising a nonplanar impacting surface of said web structure
which responds with angular contortion upon occurrence of said lateral impact, thereby
decreasing the moment of inertia of said delineator during bending motion, reducing
said EI product from a longitudinal rigid structure to a flexible structure during
deformation.
22. A delineator as defined in claim 21, wherein said material composition includes
material selected from the group consisting of thermosetting resins, thermoplastic
resins and combinations thereof.
23. A delineator as defined in claim 21, wherein said web structure comprises a planar
section with at least one longitudinal rib extending forward therefrom.
24. A delineator as defined in claim 23, wherein said web structure includes two longitudinal
ribs extending forward from the respective sides of said delineator, with a third
longitudinal rib extending rearward from a central area of a backside of said delineator.
25. A delineator as defined in claim 21, wherein the web structure comprises a concavo-convex
structure for the front and backside, respectively, of said delineator.
26. A delineator as defined in claim 25, further comprising a longitudinal rib to
increase longitudinal rigidity.
27. A delineator as defined in claim 25, wherein longitudinal ribs extend from sides
of said concavo-convex web structure.