[0001] The invention relates to a method and device for transporting sediment, particularly
sand, along a bottom of a water mass. More specifically, the invention relates to
a method and device for transporting sand from a deeper-lying part of a seabed to
a coast for the purpose of forming a natural sea defence.
[0002] Dunes form a natural sea defence and protect coastal areas lying therebehind. In
the past, dunes were created by waves transporting sand to the coast. The generally
onshore wind blew the sand landward, where it was captured by vegetation. This is
how the dunes were formed and fed for centuries.
[0003] This process gradually came to a standstill because the bottom became deeper as a
result of the fact that the sand had been transported to the coast, while the sea
level was rising at the same time. The waves were hereby no longer able to mobilize
the sediment on the bottom. Sand was hereby no longer supplied from the deeper parts
of the coastal foundation - the part of the coastal profile between the 20 m isobath
and the 12 m isobath - to the nearshore coastal zone - the part of the coastal profile
from the 8 m isobath to the beach.
[0004] The sea level did however continue to rise, whereby the waves above the deeper part
were no longer able to set the bottom into motion and were no longer able to generate
coastward transport. The supply of sand hereby came to a halt and the waves began
attacking the coast rather than building it up. With each storm, sand was washed away,
referred to as coastal erosion, but this sand was no longer supplied during calm periods.
Over the years, this resulted in erosion of the coast; the phenomenon that, on average,
more sand disappeared from a coast section than accumulated there.
[0005] Considering the importance of dunes for coastal protection, the government of the
Netherlands decided in 1990 that the coast would be maintained as it was then by means
of sand nourishments. The supply of sand which had ceased on the geologic time scale
was hereby reinstated in artificial manner. Starting in the nineties, an average of
7 million m
3 of sand is replenished annually in coast sections along the Dutch coast. The sand
is extracted in the deeper parts (deeper than -20 m) and brought to the coast.
[0006] The technique of sand nourishment (extraction, transport, nourishment) is an artificial
alternative for the loss of a natural constant supply of sand from the shallow marginal
sea to the coast. In beach nourishment the sand is pumped to the beach via a pipeline
by a trailing suction hopper dredger. Bulldozers distribute the sand further over
the beach.
[0007] During previous periods multiple studies have already been carried out into the way
sand behaves in the dynamic coastal zone. The European project NOURTEC (NOURishment
TEChnology), part of the European research programme MAST (Marine Science and Technology),
has shown that underwater shoreface nourishment is highly effective:
https://cordis.europa.eu/project/rcn/5620/factsheet/en. Sand which is deposited on the shallow foreshore (at a depth of around 6 m) lies
within reach of the waves. The wave forces transport the sand in the direction of
the coast. Active beach nourishment by means of pumping sucked-up sand via a pipeline
is then not necessary.
[0008] At this point, climate change is intensifying. There is an urgent need to reduce
CO
2 emissions. Replenishing the Dutch coast in conventional manner is accompanied by
high CO
2 emission. The extraction and transport of the sand with dredging vessels requires
a lot of energy, which in the case of dredging vessels is produced by combustion engines
running on fuel oil.
[0009] The invention has for its object to provide a method and device with which sand can
be replenished with lower CO
2 emission than can be achieved with the conventional nourishment techniques.
[0010] According to the invention, this is achieved in a method as described in the preamble
by the steps of:
- placing at least one obstacle at a starting position on the bottom at the position
of a flow in the water mass, such that the flow sets a part of the bottom around the
at least one obstacle into motion and urges it in a desired transport direction; and
- displacing the at least one obstacle to a subsequent position in the transport direction
after some time.
[0011] A sand transport in a determined direction can thus be initiated simply by suitable
placing of the at least one obstacle, without using suction elements and pipelines.
[0012] In an application of the method the water mass can be a sea, the flow can be a tidal
flow, and the sand can be transported from a deeper-lying part of the seabed in the
direction of the coast. The obstacle placed on the bottom thus provides for sand being
transported from the deeper parts of the coastal profile in the direction of the coast
and thus coming into reach of wave forces which can move the sand further onto the
coast. The invention can thus make use of the natural forces which are present in
a marginal sea like e.g. the North Sea every day, i.e. tide and waves. The invention
is based on the phenomenon of scouring; when an obstacle is placed in the coastal
zone, a scour hole results. The tidal flow accelerates around the obstacle and entrains
sediment. A scour hole is created at the foot of the obstacle until a determined equilibrium
is reached. This principle thus forms the basis of the operation of the invention;
placing an object in a coastal zone induces a temporary sand transport.
[0013] In order to accelerate the sand transport in the direction of the coast the step
of displacing the at least one obstacle in the transport direction can be repeated
multiple times.
[0014] In an embodiment of the method the at least one obstacle is profiled and the profile
of the at least one obstacle determines the transport direction. The shape of the
obstacle influences the size of this sand transport; a shape which brings about a
great acceleration will result in a greater scour hole, and will thus cause a greater
sand transport.
[0015] The bottom in the vicinity of the at least one obstacle can be monitored and on the
basis of the monitoring it can be determined when the at least one obstacle will be
displaced to a subsequent position. The sand transport toward the coast can thus be
controlled.
[0016] In order to increase the output and ensure a uniform replenishment of sand a plurality
of obstacles can be placed on the bottom in a pattern and be displaced, optionally
synchronously.
[0017] The invention also relates to a device for transporting sediment, particularly sand,
along a bottom of a water mass, whereby the above described method can be performed.
Such a device is provided according to the invention with at least one obstacle placeable
on the bottom and means for displacing the at least one obstacle in a desired transport
direction. The displacing means can be driven electrically, hydraulically or pneumatically.
The displacing means can for instance comprise driven wheels or caterpillars, whereby
the obstacle can travel over the bottom. It is also possible to envisage the displacing
means comprising displaceable suction anchors with electric pumps, pull rods and a
control, whereby it is possible to have the obstacle "walk" over the bottom, as it
were.
[0018] As discussed above, the at least one obstacle can be profiled for the purpose of
determining the transport direction. The at least one obstacle can particularly have
a protruding part which points in the transport direction.
[0019] In order to have the obstacle be effective in two substantially opposite flow directions
of the water, for instance in tidal flow, the obstacle can be symmetrical relative
to a line running transversely of the flow directions. The shape of the obstacle can
thus for instance be substantially triangular, with a base running substantially parallel
to the coastline and two oblique sides directed from the base to the coastline and
converging in an angular point - or, seen three-dimensionally, an edge. The triangle
is a shape which brings about a great acceleration and thus causes a great sand transport.
[0020] The at least one obstacle can have hollow parts on either side of the protruding
part. The slightly hollow profile of the oblique sides ensures a uniform guiding of
the flow from the base in the direction of the point.
[0021] In order to ensure that the obstacle/the obstacles is/are displaced only at a desired
moment and in a desired direction, the device can further be provided with means for
at least temporarily anchoring the at least one obstacle to the bottom. These optionally
temporary anchoring means can comprise one or more suction anchors.
[0022] The device according to the invention can be provided with means for monitoring the
bottom in the vicinity of the at least one obstacle. Such monitoring means can comprise
sensors which detect the state of the bottom and on the basis thereof generate a signal
that forms a measure of the effectiveness of the obstacle. The sensors can form part
of a so-called multibeam echosounder.
[0023] In an embodiment the above described device is further provided with means, connected
to the monitoring means, for determining when the at least one obstacle must be displaced
to a subsequent position. These determining means can comprise a processor which receives
and processes signals from the sensors and on the basis thereof determines that a
state of equilibrium has been reached. This happens when the obstacle has been at
a determined location for some time, and results in the sand transport coming to a
standstill. At that moment the determining means indicate that the obstacle must be
displaced.
[0024] As stated above, a uniform sand transport can be achieved when the device is further
provided with a plurality of obstacles which can be placed on the bottom in a pattern
and can be displaced, optionally synchronously.
[0025] The invention is now elucidated on the basis of an example, wherein reference is
made to the accompanying drawings, in which:
Fig. 1 is a cross-section of a coastal profile with a wave-dominated zone and a portion
affected by the invention;
Fig. 2 is a perspective view of a coast with an embodiment of the device according
to the invention with a single obstacle and the associated sedimentation and erosion
patterns;
Fig. 3 is a perspective view of the coast with another embodiment of the device according
to the invention with a number of obstacles and the associated sedimentation and erosion
patterns;
Fig. 4 is a schematic view of an obstacle on a bottom of a water mass and the deformation
of the bottom under the influence of flow of the water mass; and
Fig. 5 is a schematic view of an embodiment of the method according to the invention.
[0026] When an obstacle 1 is placed on a bottom 2 of a water mass (Fig. 4), a flow F of
the water mass is hereby in principle disrupted. This disruption of the water flow
F results in an accelerated flow along the obstacle 1 and a turbulent wake Z downstream
of obstacle 1, whereby sediment, for instance sand, is dislodged from bottom 2. This
dislodged sand is entrained by the flowing water mass, and eventually settles at some
distance downstream of obstacle 1 when the speed of the water flow becomes low. The
dislodged sand can thus be transported over a determined distance. This eventually
creates a cavity or scour hole 4 (shown in broken lines) in bottom 2 around obstacle
1, while an accumulation 5 of sand (likewise shown in broken lines) is created further
downstream of obstacle 1. The form of the bottom around the obstacle is in equilibrium
and corresponds to the flow profile. At positions where the water flows more quickly
it is deeper and at sheltered positions it is more shallow.
[0027] This principle forms the basis of the operation of the invention. By placing the
obstacle 1 at a different position after some time (shown with broken lines in Fig.
4) such a sand transport can also be caused there. By repeatedly displacing obstacle
1 in the direction of the flow a considerable amount of sand can thus eventually be
transported in the flow direction.
[0028] When the flow direction changes however, the transport direction of the dislodged
sand will also change. In the case of a tidal flow a full reversal of the flow direction
takes place. In order to achieve the same transport direction T of the dislodged sand
both in an outgoing tidal flow and an incoming tidal flow (shown with double arrows
F
T in Fig. 2 and Fig. 3) obstacle 1 can take a substantially symmetrical form relative
to a line of symmetry 6 running substantially transversely of the tidal flow F
T. Obstacle 1 can here have a protruding part 7 which points in the transport direction
T.
[0029] In the shown embodiment obstacle 1 is substantially triangular in top view, with
a base 8 which is substantially parallel to the incoming and outgoing tidal flows,
and two sides 9 which converge in an apex, which is formed in three-dimensional obstacle
1 by an end edge 10. The basic shape of obstacle 1 is here thus an isosceles triangle,
albeit that the equal sides are not straight but have a hollow profile. The flow which
hits the side 9 lying upstream is hereby deflected evenly in the direction of end
edge 10, so in transport direction T. The transport direction T is directed toward
the coastline C, and is thus transverse to the tidal flow F
T which runs substantially parallel to the coastline C.
[0030] Owing to the even deflection by means of the side 9 with a hollow profile, the flow
is accelerated there and the sand is washed away (erosion, shown schematically by
the sand clouds E), after which this sand settles again at some distance coastward
from obstacle 1 (sedimentation, designated by the sand clouds S). Due to the symmetrical
form of obstacle 1 this phenomenon occurs both during the incoming tidal flow and
during the outgoing tidal flow which is opposite thereto. A net sand transport in
the desired direction, in this case in the direction of the coastline C, thus results
over a full tidal cycle. In order to intensify this effect obstacle 1 can further
be provided with flow guides, such as for instance twisted flow edges for setting
water flowing past into a swirling motion.
[0031] As stated, an equilibrium will result around obstacle 1 after some time. The form
of the bottom around obstacle 1 then corresponds to the flow profile, with deeper
parts where the flow speed is higher and shallower parts in the area sheltered by
obstacle 1. It is then time to adapt, and displace obstacle 1 over determined distance,
for instance a few metres in the direction of the coastline C, so that the accumulated
sand S2 is once again swirled up by the tidal flow and is transported further coastward
again.
[0032] For the purpose of displacing obstacle 1 displacing means (not shown here) can be
provided, for instance in the form of large wheels with which obstacle 1 can travel
over bottom 2. Caterpillars can also be envisaged instead of wheels. The wheels or
caterpillars can be driven electrically, hydraulically or even pneumatically, although
in practice an electric drive is preferred. It is also possible to have obstacle 1
"walk" over bottom 2 by means of displaceable suction anchors with electric pumps,
pull rods and a control, which together can form the displacing means. The electrical
energy required for the displacement can be generated by solar panels or wind turbines
and can be stored in batteries.
[0033] When obstacle 1 is placed at a determined position it must remain there until a state
of equilibrium has been reached. For this purpose obstacle 1 takes a heavy form in
the shown embodiment, for instance of stainless steel or composite material weighted
with concrete. When the weight of obstacle 1 is insufficient to keep it in place,
the obstacle can also be provided with anchoring means (not shown here either), for
instance in the form of one or more suction anchors. These suction anchors can simultaneously
play a part in the displacement of obstacle 1, as described above.
[0034] In order to determine when obstacle 1 must be displaced an electronic control system
can be used (not shown here). This control system can co-act with sensors (not shown
here either) that monitor the changes in bottom 2, and can determine on the basis
of signals from these sensors when a situation of equilibrium of bottom 2 has resulted
and how far obstacle 1 must then be shifted. As stated, use can for instance be made
for this purpose of a multibeam echosounder.
[0035] With a view to safety, the device must have sufficient signalling for transiting
shipping traffic and for fishery. For this purpose it is necessary for a part of obstacle
1 to protrude above water. This can however be a slender part, for instance masts
or a frame, which experiences little resistance from the waves.
[0036] In order to be able to increase the transport capacity of the device a plurality
of obstacles 1 can be placed in each other's vicinity in a pattern (Fig. 3). These
obstacles 1 can be displaced either synchronously or in a determined order in the
direction of the coast C, somewhat in the manner of a crab moving its legs. The device
is therefore also referred to as "sand crab".
[0037] Depending on the sand nourishment requirement, such devices can be placed at multiple
locations in the coastal zone, whereby coastward transport of sand occurs at multiple
locations.
[0038] The steps of the method according to the invention are summarized in Fig. 5. Obstacle
1 is in the first instance placed at a determined position on the bottom 2 of a water
mass 3, for instance the seabed close to the coast (step 100). The obstacle 1 can
then be anchored at that position (step 101). The flow is affected as a result of
the presence of obstacle 1, whereby sand is dislodged from bottom 2 in the desired
direction, is for instance transported to the coast. The state of the bottom 2 around
obstacle 1 is monitored continuously (step 102). On the basis of data from this monitoring
it is determined whether a state of equilibrium has been reached (step 103). If this
is not yet the case, the state is monitored further (step 102). If it is determined
that an equilibrium has been reached, obstacle 1 is displaced over a determined distance
(step 104). At the new position the obstacle 1 is anchored once again (step 101) and
the transport of sand continues.
[0039] The device according to the invention is thus not a static apparatus; it is an apparatus
that advances slowly. The speed of movement is determined by the speed at which the
situation of equilibrium of the bottom is reached. In the case of turbulence due to
high waves and in the case of spring tide the state of equilibrium will be reached
sooner than in the case of low waves and slack water. The displacement of the obstacle
must thus be determined by a mechanism which measures the changes in the bottom around
the obstacle.
[0040] As stated, this technique provides for an integral transport of sand. Very strictly
speaking, all three stages of conventional sand nourishment by means of suctioning,
pumping and distributing sand are included;
- 1. Extraction; if extraction means mobilizing sand and readying it for transport,
then the mechanism of scouring is the same as extraction.
- 2. Transport; the asymmetrical form of the obstacle results in transport of sand toward
the coast.
- 3. Nourishment; scouring is local and the sand will automatically settle some distance
from the obstacle.
[0041] The sequence "extraction-transport-nourishment" has hereby become a continuum.
[0042] The invention can be applied to any sandy coast that experiences tidal flow. It can
be applied to the portion 11 of the coastal profile (Fig. 1) where the waves usually
do not generate coastward sand transport because it is too deep there. The waves present
will intensify the principle. Depending on how robustly the system is embodied and
on the scale, the system can work continuously; it 'stands' (or actually crawls) in
the coastal zone and, owing to the two flow-guiding sides, the device moves a volume
of sand in the direction of the coastline C during every outgoing and incoming tidal
flow. In the wave-dominated zone 12 of the coastal profile the waves take up the transport
function.
[0043] The invention could also work in a situation in which water constantly flows in the
same direction, for instance in a river. The obstacle would then not need to have
a flow-favouring profile form on two sides, but only on one side.
[0044] The environmental impact of the method and device according to the invention is minimal.
The device according to the invention is a large and heavy installation which advances,
electrically driven, in the direction of the coast at a low speed determined by an
electronic system. The device generates only minimal emissions here. The only environmental
impact is the construction, placing and displacing of the device. Following a cycle
of 'crawling towards the coast' the device must be displaced toward the sea again.
[0045] The method and device according to the invention are particularly cost-effective;
the costs lie mainly in the construction of the device. The operational costs are
limited; once it has been placed in the sea, the device can do its work almost passively,
and so at minimal cost.
[0046] The invention makes it possible to bring about a coastward sand transport in a semi-passive
manner. This sand transport is not large-scale, but is present continuously with every
outgoing and incoming tidal flow. The device can be scaled up in simple manner. The
ideal scale depends on the hydraulic regime and on the sand characteristics. The invention
can in any case be scaled up per installation - for instance a device with 8 obstacles
or with 20 obstacles - but also in number, by placing more devices per coast section.
All this also depends on the influence of the obstacles on each other.
[0047] The device according to the invention is reliable since it is a relatively simple
installation with few movable parts.
[0048] Robustness is a design requirement for the device. The device must be seaworthy in
the coastal zone seaward of the surf zone in extreme conditions. The device is embodied
with suction anchors which are activated at least in the event of extreme storms.
The device does not enter the surf zone, but conversely ensures that the sand is transported
from deeper-lying parts of the coast in the direction of the surf zone. There, the
waves take over; the wave-driven sand transport which provides for the build-up of
a coast.
[0049] Although the invention is described above on the basis of a number of embodiments,
it will be apparent that it is not limited thereto and can be varied in many ways
within the scope of the following claims.
1. Method for transporting sediment, particularly sand, along a bottom of a water mass,
comprising the steps of:
- placing at least one obstacle at a starting position on the bottom at the position
of a flow in the water mass, such that the flow sets a part of the bottom around the
at least one obstacle into motion and urges it in a desired transport direction; and
- displacing the at least one obstacle to a subsequent position in the transport direction
after some time.
2. Method according to claim 1, wherein the step of displacing the at least one obstacle
in the transport direction is repeated multiple times.
3. Method according to claim 1 or 2, wherein the at least one obstacle is profiled and
the profile of the at least one obstacle determines the transport direction.
4. Method according to any one of the foregoing claims, wherein the bottom in the vicinity
of the at least one obstacle is monitored and it is determined on the basis of the
monitoring when the at least one obstacle will be displaced to a subsequent position.
5. Method according to any one of the foregoing claims, wherein a plurality of obstacles
are placed on the bottom in a pattern and are displaced, optionally synchronously.
6. Method according to any one of the foregoing claims, wherein the water mass is a sea,
the flow is a tidal flow, and the sand is transported from a deeper-lying part of
the seabed in the direction of the coast.
7. Method according to claims 3 and 6, wherein the at least one obstacle is profiled
such that the transport direction in incoming tidal flow is substantially the same
as the transport direction in outgoing tidal flow.
8. Device for transporting sediment, particularly sand, along a bottom of a water mass,
comprising at least one obstacle placeable on the bottom and means for displacing
the at least one obstacle in a desired transport direction.
9. Device according to claim 8, wherein the at least one obstacle is profiled for the
purpose of determining the transport direction.
10. Device according to claim 9, wherein the at least one obstacle has a protruding part
which points in the transport direction.
11. Device according to claim 9 or 10, wherein the obstacle is symmetrical relative to
a line running transversely of two substantially opposite flow directions of the water
mass.
12. Device according to claims 10 and 11, wherein the at least one obstacle has hollow
parts on either side of the protruding part.
13. Device according to any one of the claims 8-12, further provided with means for at
least temporarily anchoring the at least one obstacle to the bottom.
14. Device according to any one of the claims 8-13, further provided with means for monitoring
the bottom in the vicinity of the at least one obstacle.
15. Device according to claim 14, further provided with means, connected to the monitoring
means, for determining when the at least one obstacle will be displaced to a subsequent
position.
16. Device according to any one of the claims 8-15, further provided with a plurality
of obstacles which can be placed on the bottom in a pattern and can be displaced,
optionally synchronously.