Field
[0001] The present invention relates to road studs, such as used for marking lanes along
a road.
Background
[0002] Road studs are in widespread use to provide visible guidance and warnings to motorists
and other road users. Such road studs typically include one or more reflectors made
out of glass or plastic to reflect light from vehicle headlights. The road studs especially
help a motorist to determine his or her position on the road during hours of darkness.
[0003] There are two main types of road stud in use in the UK (although other intermediate
or hybrid types of road stud are also available). A first type is generally known
as a "stick on", and is normally formed from a plastic unit incorporating one or more
plastic reflectors. Plastic stick-on reflectors are placed on top of the surface of
the road and are attached to the road by adhesive. They are relatively cheap but also
have a relatively short life-time. For example, they may become detached from the
road surface by passing traffic, and/or the visibility of the reflector may become
reduced, for example by dirt being deposited onto the surface of the reflector.
[0004] A second type of road stud in use in the UK is a depressible (also sometimes referred
to as a "cat's eye"). This comprises a base unit, normally made of cast iron, which
holds a resilient insert. The insert is typically made of rubber, and carries one
or more glass or plastic reflectors. This type of road stud is installed by drilling
a hole in the road, and then bonding the road stud into location using bitumen.
[0005] In some common situations, the inserts for depressible road studs may be provided
with one or more wiper blades. When the insert is compressed, for example because
a lorry has driven over the road stud, these blades are designed to wipe across the
reflectors. This helps to keep the surface of the reflectors free from dirt, and hence
helps to maintain high visibility.
[0006] One example of a depressible road stud is described in
GB 2263298 B. A road stud generally in accordance with this patent is sold commercially under
the "Light Dome" trademark by Industrial Rubber Ltd, of Fareham, Hampshire. The insert
described in this patent includes ducts to allow water that has collected in the base
of the road stud to be applied to the wiper blades. The water helps to lubricate the
wiping action of the blades on the reflectors, thereby reducing wear, as well as assisting
with the overall cleaning process.
[0007] There is a continued interest in improving the properties or road studs, for example,
to enhance visibility. Existing prior art includes
GB 0,651,541 A, which relates to supports for road studs.
Summary
[0008] The invention is defined in the appended claims.
Brief Description of the Drawings
[0009] Various implementations in accordance with the claimed invention will now be described
in detail by way of example only with reference to the following drawings:
Figure 1 is a front view of a road stud in accordance with some examples of the invention;
Figure 2 is a perspective view of the road stud of Figure 1.
Figure 3 is a front view of a reflector for fitting to the road stud of Figure 1.
Detailed Description
[0010] Figure 1 illustrates a front view of a road stud 100 to be provided with one or more
reflectors in accordance with some example implementations of the invention, while
Figure 2 illustrates a perspective (isometric) view of the same road stud as shown
in Figure 1. The front of the road stud is considered to be the end facing oncoming
traffic for normal installation of the road stud in a road. It will be appreciated
that in some implementations, the road stud is provided with a reflector (or reflectors)
at just one end. This might typically be the case, for example, for a road stud which
is being used to mark the edge of the road, and hence is primarily intended to be
visible to vehicles travelling along next to this edge (in contrast to vehicles travelling
in the opposite direction, which will typically be on the opposite side of the road).
In other cases, both the front end and the back end of the road stud may be provided
with reflectors, in which case the road stud typically has bi-directional symmetry
- i.e. the front and back are the same. Such a symmetric road stud might be located,
for example, along the centre-line of a road, so as to provide visibility (reflectivity)
to traffic coming in both directions. Although many implementations of a bi-directional
road stud will have the same reflectors front and back, in some cases the reflectors
front and back may be different. For example, the reflector in one direction (which
we can regard as the front) might be green in colour, to indicate that a vehicle is
allowed to advance in this direction (past the road stud), while the same road stud
may have a reflector in the opposite direction (which we can regard as the back) which
might be red in colour, to indicate that a vehicle should not advance in this direction.
[0011] The body of the road stud 100 is generally made of cast iron, with the one or more
reflectors then being bonded or attached (e.g. glued) to the road stud 100. In other
implementations, the body of the road stud may be made of some other metal, or alternatively
of moulded plastic, or any other suitable material(s). In some implementations, the
body of the road stud 100 may be formed from multiple components, which are bonded
or otherwise connected together to form the road stud.
[0012] The road stud 100 can be considered as having a lower section 102, for bonding to
the road, and an upper section 101, which provides one or more reflectors. After installation,
the lower section 102 is typically beneath (submerged into) the road surface and the
upper section 101 typically stands above the road surface.
[0013] In the example of Figure 1, the lower section 102 of the road stud 100 is formed
from a circumferential wall having a substantially circular (annular) shape. In particular,
the wall includes a lower lip 105 and an upper lip 106 separated by (defining) a channel
107. The lower lip 105 defines the base of the road stud 100 and has a circular profile.
The upper lip 106 is shown as coaxial to the lower lip 105, but the upper lip 106
may have a smaller diameter than the lower lip 105 (as shown in Figure 1). The top
edge of upper lip 106 may be considered to define the boundary between the upper section
101 and the lower section 102. For example, after installation the upper edge of upper
lip 106 is approximately flush (i.e. level) with the road surface.
[0014] Between the upper lip 106 and lower lip 105 is the channel 107, which extends around
the circumference of the lower section 102 of the road stud 100. The channel is likewise
circular (circumferential) in shape, but with a smaller cross-sectional profile (radius)
than the lower and upper lips 105, 106.
[0015] The underside of the lower section 102 includes a central cavity defined by the outer
wall (not visible in Figure 1). The cavity (hollow, recess, void) is formed within
the lower section 102 such that the lower lip 105 (at least) has an annular profile.
Several flow holes 108 extend through the circumferential wall, in particular through
the lower lip 105 and channel 107, to provide connectivity (access) to the central
cavity. In the example shown in Figure 1, the road stud 100 has four flow holes 108,
namely front, back, and on opposing sides (only two of the flow holes 108 are visible
in Figure 2). The size, shape, number and location of the flow holes 108 may be dependent
on the shape of the cavity and the overall properties of the road stud 100 etc.
[0016] In a typical installation process, a hole which is slightly wider than the road stud
100 is drilled into a road surface to a depth corresponding approximately to the height
of the lower section 102. Bitumen (or some other similar material to act as road grout)
is then poured into the hole, after which the road stud 100 is placed into the hole.
As the bitumen fills the cavity within the lower section 102, the flow holes 108 allow
air from the cavity to escape from the cavity, being displaced therein by the bitumen.
Accordingly, the flow holes 108 help to prevent air from being trapped within the
cavity during installation to ensure a consistent and reliable bonding of the road
stud to the road as the bitumen solidifies. Note also that the bitumen fills channel
107 and hence overlies lower lip 105, again helping to retain the road stud 100 in
position.
[0017] The upper section 101 of the road stud comprises a raised bar or ridge 110 which
extends in a transverse direction from one side of the road stud 100 to the other
side - i.e. the ridge is formed in a direction perpendicular to the front-back axis
of the road stud 100. Accordingly, the ridge comprises a pair of approximately vertical
faces (sides) 115, one facing to the front of the road stud (as visible in Figure
1) and one facing to the rear of the road stud (not visible in Figure 1). A reflector
is supported on the front face 115 of ridge 110, and a second reflector may also be
provided if desired on the back face 115 of ridge 110 (not visible in Figure 2). First
and second side walls 112 are formed at respective ends of the ridge 110, in other
words, the ridge 110 terminates at these side walls 112. The side walls help to protect
the road stud 100, and in particular the reflector(s), from damage by passing vehicles
(and also help to smooth the ride of such vehicles over the road stud).
[0018] Each of the faces 115 is provided with a recess 116 to receive a respective reflector
(Figures 1 and 2 show the road stud before the reflectors are fitted). When the reflector
is fitted into the corresponding recess 116, the outer surface of the reflector is
generally substantially flush (level or flat) with the respective face. Each reflector
may be retained in the recess 116 by suitable fixing means, for example by using adhesive,
clips (or other mechanical mechanism), and so on. Although Figure 1 shows a single
recess 116 on face 115 for receiving a single reflector, in other implementations
there may be more than one recess per face 115 to allow multiple reflectors to be
fitted onto a single face (or alternatively a single recess 116 may potentially be
configured to receive multiple reflectors). As mentioned above, a road stud may be
designed for use in a single direction (a front reflector only), or for bi-directional
use (front and back reflectors). In the former case, a reflector may be fitted onto
only a single face 115 of the bar 110 (and the opposing face, not visible in Figure
2, may not be provided with a recess).
[0019] The road stud 100 is designed so that a reflector fitted into the recess 116 is unobscured
in the direction normal to its face 115, i.e. from the front. In particular, the road
stud 100 includes a flat surface 118 at the front which extends from the bottom of
face 115 to the front of the road stud 100 (a similar surface is also provided at
the back of the road stud, as shown in Figure 2, for bidirectional use). It will be
appreciated that this flat surface 118 allows oncoming vehicles to have good visibility
of the reflector located in recess 116. In general, the flat surface 118 is approximately
level with (or slightly above) the road surface after installation of the road stud
100. In addition, the flat surface 118 may have a slight gradient downwards from the
face 115 towards the top lip 106 (for example, by an angle in the range 1-20 degrees,
more preferably 2-12 degrees, thereby helping to remove rainwater, etc from the road
stud, and to avoid pooling of water.
[0020] The top surface of the ridge 110 is patterned to direct rainwater falling onto the
top of the ridge to flow down over the surface of the one or more reflectors provided
in the road stud 100, thereby helping to keep the surfaces of the reflectors clean
(since if dirt accumulates on the reflector surfaces, the performance of the reflector
will tend to degrade, both in terms of the amplitude and directionality of reflected
light).
[0021] In the example shown in Figures 1 and 2, the top (patterned) surface of the ridge
100 includes a set of raised platforms 120 between which channels (grooves) 122 are
formed. Other than for the channels 122, the patterned surface of the ridge is substantially
flat and horizontal - i.e. the surfaces of the raised platforms 120 are substantially
flat and horizontal. The example of Figure 2 shows three channels 122, but it will
be appreciated that in other implementations there may be a different number of channels
(such as one channel, two channels, or four or more channels). Likewise, the example
of Figure 2 shows an equal spacing of the three channels, however, other implementations
may have a different spacing.
[0022] Each of the channels is configured to receive water present on the top of the ridge
110, such as rainwater falling onto the ridge. The end of each channel widens to form
a delta portion 124. Also shown in Figure 2, the edge of each platform 120 parallel
to the top edge of face 115 may be sloped towards the face 115 (rather than being
configured vertically like the other edges). This sloping again helps to direct rainwater
onto the insert, and also can provide greater resilience for contact with passing
vehicles. Similarly, the delta portions 124 may likewise be slightly inclined downwards
from the channels 122 towards the face 115 to help water flow in this direction. (The
angle of inclination is typically small, for example, an angle in the range 1-20 degrees,
more preferably 2-12 degrees).
[0023] By way of example only, the width of the ridge or bar 110 (from one face 115 to the
other) may be in the range of 20 to 60 mm, and typically around 40 mm. The width of
each raised platform 120 (corresponding also to the separation of adjacent channels
122) may be in the range of 10 mm to 40 mm and typically around 20 mm. Each channel
122 may have a width of 1 to 5 mm, and may have a length of between 40% and 60% of
the width of the ridge (prior to the delta portion at each end of the channel). Each
channel 122 may additionally have a depth of between 0.5 and 3 mm, and typically around
1 mm. It will be appreciated that these dimensions are given by way of example only,
without limitation, and will vary according to the circumstances of any given road
stud, such as being dependent on the number of channels provided on the ridge 110.
[0024] Furthermore, it will be appreciated that the length of the channels 122 relative
to the delta portions 124 can be altered. In some cases, the channels 122 may shrink
to have little or no length, in which case the patterning is based on the provision
of the delta portions, while in other cases, the delta portions 124 may be omitted,
such that the channels extend to the edge of face 115. A full range of intermediate
configurations may also be implemented. (Note that if the delta portions are reduced
in size, this may allow a higher number of channels to be formed in the top surface
of the ridge 110).
[0025] The patterned top surface of ridge 110 is configured so that rainwater falling onto
the ridge 110 fills the channels 122 and then flows into delta portions 124, which
act to direct the water over the external surface of a reflector mounted in recess
116. This flow of water helps to clean the surface of the reflector, for example,
by removing dust and other dirt which may otherwise hinder the operation of the reflectors.
The widening of the delta portions 124 helps to provide a more uniform flow of water
across the majority of the reflector surface.
[0026] Note that the depth of the patterning (such as channels 122) may also be used to
provide an indication of the wear of the road stud 100. For example, if the road stud
100 has experienced heavy use (a high volume of passing vehicles travelling over the
road stud), then the raised platforms 120 may be eroded such that the depth of the
channels 122 is reduced. Accordingly, inspection of the groove depth may be used to
provide an indication to a user that replacement of the road stud 100 is advisable.
[0027] Although Figure 2 provides one example of a patterned surface, the skilled person
will be aware of many other potential variants. For example, while the patterned surface
of Figure 2 shows three channels 122 connecting to six delta portions 124, in other
examples there may be more or fewer channels and delta portions. In addition, although
Figure 2 shows a patterning having a first height for the top surface of the raised
platforms 120 and a second height for the bottom surface of the channels 122, in other
implementations there may be a greater number of heights. For example, rather than
having a single height, the raised platforms 120 may have a continuous or stepped
gradient with a greatest height in the centre of the platform, and a lower height
bordering the channel 122. Changes in height (gradients) may be continuous or stepped
(discontinuous). Likewise, rather than having linear channels 122 such as shown in
Figure 2, in other implementations the channels may include bends, angles or curvature
as appropriate. Additionally, while in Figure 2 each groove or channel is independent
of other channels, in other implementations the channels may be interconnected; for
example the channels may form a criss-cross pattern or similar. Likewise, in some
implementations, the different delta portions 124 may potentially join together (e.g.
in their wider regions). Accordingly, the skilled person will appreciate that the
topography (topology) of the patterned surface may have a wide variety of potential
configurations dependent upon the circumstances of any given road stud.
[0028] Figure 3 depicts an example of a reflector 200 to fit into the recess 116 of the
road stud 100 of Figures 1 and 2. The reflector 200 has a shape corresponding to the
recess 116, such that when reflector 200 is inserted into the recess 116, the external
(reflective) surface of the reflector 200 is substantially flush with face 115 of
the road stud 100 surrounding the recess 116. Accordingly, rainwater directed by the
patterned surface at the top of the ridge (bar) 110 runs down this reflective surface
to help keep the reflector clean. The reflector 200 shown in Figure 1 comprises a
number of individual reflector components 210, but other reflectors may have a different
structure, and the road stud 100 can be fitted with any suitable reflector providing
a high reflectance (such reflectors are, in themselves, well-known in the art).
[0029] Although Figures 1-3 depict an example of a road stud 100 in accordance with the
present invention, the skilled person will be aware of many possible modifications.
For example, in implementations in which a reflector is only provided for one direction,
the ridge or central bar 100 may extend to (and slope down towards) the rear of the
road stud, thereby giving the rear portion of the road stud 100 more of a (half) dome-like
appearance.
[0030] Furthermore, the skilled person will be aware of many possible variations for the
lower portion 102 of the road stud (below the road surface in use). For example, the
lower portion 102 of road stud 100 may be elongated to have an elliptical or oval
shape (in plan view), or have any other suitable shape, such as square or hexagonal.
In addition, the flow holes 108 may be omitted in some implementations, and the cavity
underneath the lower section might be replaced by a more complex configuration of
openings.
[0031] In summary, a road stud is disclosed herein. The road stud includes a reflector having
a reflective surface, for example, for providing drivers with markings on the road
at night by using reflections from vehicle headlights. The road stud includes a patterned
surface configured to direct rainwater falling on the road stud to flow down over
the reflective surface of the reflector, thereby helping to clean the reflector surface
and maintain a high level of performance (such as high reflectivity, without scatter).
[0032] The patterned surface has a topography to direct the water flow as desired, and the
patterned surface comprises a plurality of channels; e.g. there may be three or more
channels to promote the flow of the rainwater. The channels widen into a delta portion
adjacent the reflector to help spread the water over a greater portion of the width
of the reflector, so that most if not all of the reflector surface experiences a cleaning
water flow. For example, the delta portions of the plurality of channels may correspond
to at least half the width of the reflector. Additionally (or alternatively), the
delta portions may be inclined downwards from the channel towards the reflector to
encourage the water flow in this direction. The remainder of the patterned surface
(i.e. other than the plurality of channels) is substantially horizontal (according
to the orientation of the road stud for normal installation into the road). Note that
the relatively flat, horizontal top of the road stud 100 prevents the road stud from
protruding too far above the road surface (which is helpful both to minimise wear
and tear on the road stud itself, and also to minimise any impact on passing vehicles).
In addition, the patterning or topography of the top of the road stud may provide
texturing to help increase tyre grip for vehicles passing over the road stud.
[0033] The road stud may have a raised portion having a substantially vertical face directed
towards the front of the road stud, wherein the reflector is mounted on the vertical
face, and wherein the patterned surface is formed on the top of the raised portion.
For example, the raised portion may comprise a central bar running transversely from
one side of the road stud to the other. The bar has two opposing, substantially vertical
faces directed towards the front and rear of the road stud, with a reflector mounted
on each of the two substantially vertical faces. For such a configuration, the channels
extend between the two substantially vertical faces such that each end of the channel
is configured to direct rainwater falling on the road stud to flow down over the reflective
surface of a respective reflector.
[0034] In conclusion, although a variety of embodiments have been described herein, these
are provided by way of example only, and many variations and modifications on such
embodiments will be apparent to the skilled person and fall within the scope of the
present invention, which is defined by the appended claims and their equivalents.
[0035] Additional embodiments include those set out in the following consistory clauses:
1. A road stud (100) including a reflector (200) having a reflective surface, wherein
the road stud includes a patterned surface configured to direct rainwater falling
on the road stud to flow down over the reflective surface of the reflector (200);
wherein the patterned surface comprises a plurality of channels (122), each channel
(122) extending in a direction towards the reflective surface, and wherein the patterned
surface is substantially flat and horizontal apart from the plurality of channels
(122), the road stud characterised in that:
each channel widens into a delta portion (124) adjacent the reflector (200).
2. The road stud of claim 1, wherein the patterned surface comprises three equally spaced
channels (122).
3. The road stud of any preceding claim, wherein the delta portions (124) of the plurality
of channels (122) extend for at least half the width of the reflector (200).
4. The road stud of any preceding claim wherein the delta portions (124) are inclined
downwards from the plurality of channels towards the reflector (200).
5. The road stud of any preceding claim, wherein the depth of the plurality of channels
(122) provides an indication of the wear of the road stud (100).
6. The road stud of any preceding claim, further comprising a raised portion having a
substantially vertical face (115) directed towards the front of the road stud (100),
wherein the reflector (200) is mounted on the vertical face (115), and wherein the
patterned surface is formed on the top of the raised portion.
7. The road stud of claim 6, wherein the raised portion comprises a central bar running
transversely from one side of the road stud (100) to the other, said bar having two
opposing, substantially vertical faces (115) directed towards the front and rear of
the road stud (100), and wherein a reflector (200) is mounted on each of the two substantially
vertical faces (115).
8. The road stud of claim 7, wherein the patterned surface comprises the plurality of
channels (122) that extend between the two substantially vertical faces (115) such
that each end of the channel (122) is configured to direct rainwater falling on the
road stud (100) to flow down over the reflective surface of a respective reflector
(200).
9. The road stud of any of claims 5 to 8, wherein the plurality of channels (122) run
in a direction between the front and rear of the road stud (100).
10. The road stud of any of claims 5 to 9, wherein the vertical face (115) includes a
recess (116) for receiving the reflector (200), and wherein the reflector surface
is flush with the vertical face (115).
11. The road stud of any preceding claim, further comprising a substantially flat surface
(118) in front of the reflector (200) to provide an unobstructed view of the reflector
(200).
12. The road stud of claim 11, wherein the substantially flat surface (118) slopes downwards
away from the reflector (200).
1. Markierungsknopf (100) mit einem Reflektor (200), der eine reflektierende Oberfläche
aufweist, wobei der Markierungsknopf eine strukturierte Oberfläche umfasst, die ausgestaltet
ist, sich auf dem Markierungsknopf niederschlagendes Regenwasser derart zu leiten,
dass es über die reflektierende Oberfläche des Reflektors (200) nach unten fließt;
wobei die strukturierte Oberfläche mehrere Kanäle (122) umfasst, wobei sich jeder
Kanal (122) in einer Richtung hin zu der reflektierenden Oberfläche erstreckt, und
wobei die strukturierte Oberfläche im Wesentlichen flach und horizontal von den mehreren
Kanälen (122) getrennt ist, wobei der Markierungsknopf dadurch gekennzeichnet ist, dass:
sich jeder Kanal zu einem Deltaabschnitt (124) weitet, der an den Reflektor (200)
angrenzt.
2. Markierungsknopf nach Anspruch 1, wobei die strukturierte Oberfläche drei gleichmäßig
beabstandete Kanäle (122) umfasst.
3. Markierungsknopf nach einem der vorhergehenden Ansprüche, wobei sich die Deltaabschnitte
(124) der mehreren Kanäle (122) über mindestens die Hälfte der Breite des Reflektors
(200) erstrecken.
4. Markierungsknopf nach einem der vorhergehenden Ansprüche, wobei die Deltaabschnitte
(124) von den mehreren Kanälen hin zu dem Reflektor (200) nach unten geneigt sind.
5. Markierungsknopf nach einem der vorhergehenden Ansprüche, wobei die Tiefe der mehreren
Kanäle (122) einen Hinweis auf den Verschleiß des Markierungsknopfes (100) liefert.
6. Markierungsknopf nach einem der vorhergehenden Ansprüche, ferner umfassend einen erhabenen
Abschnitt mit einer im Wesentlichen senkrechten Fläche (115), die hin zu der Vorderseite
des Markierungsknopfes (100) ausgerichtet ist, wobei der Reflektor (200) an der senkrechten
Fläche (115) angebracht ist, und wobei die strukturierte Oberfläche an der Oberseite
des erhabenen Abschnitts ausgebildet ist.
7. Markierungsknopf nach Anspruch 6, wobei der erhabene Abschnitt eine mittlere Leiste
umfasst, die quer von einer Seite des Markierungsknopfes (100) zu der anderen verläuft,
wobei die Leiste zwei gegenüberliegende, im Wesentlichen senkrechte Flächen (115)
aufweist, die hin zu der Vorderseite und der Rückseite des Markierungsknopfes (100)
ausgerichtet sind, und wobei der Reflektor (200) an jeder der zwei im Wesentlichen
senkrechten Flächen (115) angebracht ist.
8. Markierungsknopf nach Anspruch 7, wobei die strukturierte Oberfläche die mehreren
Kanäle (122) umfasst, die sich zwischen den zwei im Wesentlichen senkrechten Flächen
(115) derart erstrecken, dass jedes Ende des Kanals (122) ausgestaltet ist, sich auf
dem Markierungsknopf (100) niederschlagendes Regenwasser derart zu leiten, dass es
über die reflektierende Oberfläche eines jeweiligen Reflektors (200) nach unten fließt.
9. Markierungsknopf nach einem der Ansprüche 5 bis 8, wobei die mehreren Kanäle (122)
in einer Richtung zwischen der Vorderseite und der Rückseite des Markierungsknopfes
(100) verlaufen.
10. Markierungsknopf nach einem der Ansprüche 5 bis 9, wobei die senkrechte Fläche (115)
eine Aussparung (116) zum Aufnehmen des Reflektors (200) umfasst, und wobei die Reflektoroberfläche
mit der senkrechten Fläche (115) bündig ist.
11. Markierungsknopf nach einem der vorhergehenden Ansprüche, ferner umfassend eine im
Wesentlichen flache Oberfläche (118) vor dem Reflektor (200), um eine ungehinderte
Sicht auf den Reflektor (200) bereitzustellen.
12. Markierungsknopf nach Anspruch 11, wobei die im Wesentlichen flache Oberfläche (118)
nach unten weg von dem Reflektor (200) abfällt.
1. Plot routier (100) comprenant un réflecteur (200) ayant une surface réfléchissante,
dans lequel le plot routier comprend une surface à motifs conçue pour diriger l'eau
de pluie tombant sur le plot routier pour qu'elle s'écoule sur la surface réfléchissante
du réflecteur (200) ;
dans lequel la surface à motifs comprend une pluralité de canaux (122), chaque canal
(122) s'étendant en direction de la surface réfléchissante, et dans lequel la surface
à motifs est sensiblement plate et horizontale excepté la pluralité de canaux (122),
le plot routier étant caractérisé en ce que :
chaque canal s'élargit en une partie en triangle (124) adjacente au réflecteur (200).
2. Plot routier selon la revendication 1, dans lequel la surface à motifs comprend trois
canaux espacés de manière égale (122).
3. Plot routier selon l'une quelconque des revendications précédentes, dans lequel les
parties en triangle (124) de la pluralité de canaux (122) s'étendent sur au moins
la moitié de la largeur du réflecteur (200).
4. Plot routier selon l'une quelconque des revendications précédentes, dans lequel les
parties en triangle (124) sont inclinées vers le bas depuis la pluralité de canaux
en direction du réflecteur (200).
5. Plot routier selon l'une quelconque des revendications précédentes, dans lequel la
profondeur de la pluralité de canaux (122) donne une indication de l'usure du plot
routier (100).
6. Plot routier selon l'une quelconque des revendications précédentes, comprenant en
outre une partie relevée ayant une surface sensiblement verticale (115) orientée vers
l'avant du plot routier (100), dans lequel le réflecteur (200) est monté sur la surface
verticale (115), et dans lequel la surface à motifs est formée au sommet de la partie
relevée.
7. Plot routier selon la revendication 6, dans lequel la partie relevée comprend une
barre centrale allant transversalement d'un côté du plot routier (100) à l'autre,
ladite barre ayant deux surfaces opposées sensiblement verticales (115) orientées
vers l'avant et l'arrière du plot routier (100), et dans lequel un réflecteur (200)
est monté sur chacune des deux surfaces sensiblement verticales (115).
8. Plot routier selon la revendication 7, dans lequel la surface à motifs comprend la
pluralité de canaux (122) qui s'étendent entre les deux surfaces sensiblement verticales
(115) de sorte que chaque extrémité du canal (122) est conçue pour diriger l'eau de
pluie tombant sur le plot routier pour qu'elle s'écoule sur la surface réfléchissante
d'un réflecteur respectif (200).
9. Plot routier selon l'une quelconque des revendications 5 à 8, dans lequel les canaux
de la pluralité de canaux (122) vont dans une direction entre l'avant et l'arrière
du plot routier (100).
10. Plot routier selon l'une quelconque des revendications 5 à 9, dans lequel la surface
verticale (115) comprend un évidement (116) destiné à recevoir le réflecteur (200),
et dans lequel la surface du réflecteur est au niveau de la surface verticale (115).
11. Plot routier selon l'une quelconque des revendications précédentes, comprenant en
outre une surface sensiblement plate (118) devant le réflecteur (200) pour permettre
une vue non obstruée du réflecteur (200) .
12. Plot routier selon la revendication 11, dans lequel la surface sensiblement plate
(118) est en pente descendante en s'éloignant du réflecteur (200).