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EP 1 497 503 B1 |
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EUROPEAN PATENT SPECIFICATION |
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Mention of the grant of the patent: |
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09.03.2011 Bulletin 2011/10 |
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Date of filing: 04.04.2003 |
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International Patent Classification (IPC):
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International application number: |
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PCT/NL2003/000257 |
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International publication number: |
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WO 2003/085208 (16.10.2003 Gazette 2003/42) |
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METHOD AND SYSTEM FOR PLACING AT LEAST ONE FOUNDATION ELEMENT IN THE GROUND
VERFAHREN UND SYSTEM ZUR ANORDNUNG MINDESTENS EINES GRÜNDUNGSELEMENTS IM BODEN
PROCEDE ET SYSTEME DE MISE EN PLACE D'AU MOINS UN ELEMENT DE FONDATION DANS LE SOL
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Designated Contracting States: |
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AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HU IE IT LI LU MC NL PT RO SE SI SK TR |
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Priority: |
04.04.2002 NL 1020304 24.07.2002 NL 1021143
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Date of publication of application: |
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19.01.2005 Bulletin 2005/03 |
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Proprietor: Gebr. van Leeuwen Harmelen B.V. |
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3481 MC Harmelen (NL) |
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Inventor: |
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- VAN LEEUWEN, Marinus, Teunis
NL-3481 MC Harmelen (NL)
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Representative: Riemens, Roelof Harm |
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Exter Polak & Charlouis B.V. (EP&C)
P.O. Box 3241 2280 GE Rijswijk 2280 GE Rijswijk (NL) |
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References cited: :
AU-A- 6 026 173 DE-A- 19 533 014 FR-A- 2 418 301 US-A- 4 742 876
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DE-A- 3 638 664 FR-A- 1 598 139 US-A- 4 637 758
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| Note: Within nine months from the publication of the mention of the grant of the European
patent, any person may give notice to the European Patent Office of opposition to
the European patent
granted. Notice of opposition shall be filed in a written reasoned statement. It shall
not be deemed to
have been filed until the opposition fee has been paid. (Art. 99(1) European Patent
Convention).
|
[0001] The invention relates to a method for forming at least one foundation element in
the ground.
[0002] A number of variants for positioning a foundation pile or deep wall of this type
are known from the prior art. For example, it is known to drive foundation piles or
deep wall elements into the ground using a pile-driver or to vibrate them into the
ground using a vibrating machine. The deep walls to be put in place generally lie
below the groundwater level, in which case they have to be substantially impervious
to groundwater.
[0003] One drawback in this respect is that the pile-driver or vibrating machines take up
a large amount of space and cause high levels of noise pollution during operation.
Moreover, high forces occur and are transmitted via the earth to at least the immediate
vicinity, which may cause damage to, for example, buildings or other existing structures.
[0004] One of the more recent developments involves using a rotary movement to twist pipes
composed of hollow pipe segments into the ground. In this case, a first pipe segment
is twisted into the ground, after which a following segment is welded to it, and then
the two segments are twisted further into the ground, etc. Grout bodies have to be
injected between adjacent pipes in order to obtain a substantially watertight deep
wall.
[0005] A drawback of this arrangement is that it is necessary to overcome considerable forces
to enable the pipes to be twisted into the ground. In this case, in particular, insurmountable
problems may arise if great depths have to be covered. The machine required to do
this is expensive to produce and also expensive to use. The fitting of the grout bodies
between the tubes is complex, and, depending on the soil composition, relatively unpredictable
and unreliable, with the result that it is difficult to ensure that the arrangement
will be impervious to groundwater.
[0006] A method according to the preamble of claim 1 is known from
FR-A-2 418 301, which shows a method for sinking a hollow tube into the ground by using a removable
drilling head which drills out earth beneath the bottom part of the tube. During sinking
the drilling head is positioned inside the lower part of the tube. Earth drilled loose
by the drilling head can be transported upwardly through the tube by means of water
injected under pressure at the level of the drilling head.
[0007] A method according to the preamble of claim 1 is also known from
US-A-4, 637, 758, regarded as the closest prior art.
[0008] It is an object of the present invention to at least partially overcome the abovementioned
drawbacks and/or to provide a usable alternative. In particular, it is an object of
the invention to provide a relatively inexpensive, environmentally-friendly, safe
and reliable method and system for positioning a foundation element which takes up
only a small amount of machinery space and can be used at any desired location without
damaging the immediate vicinity.
[0009] This object is achieved by a method according to claim 1. According to the method,
a hollow foundation element is introduced into the ground in a substantially upright
position. At the same time as it is being introduced into the ground, a removable
drilling head is active beneath the bottom part of the foundation element. The drilling
head drills out the earth which the foundation element would otherwise come into contact
with while it is being sunk into the ground. For this purpose, the drilling head is
provided with at least one excavating member which can rotate about a drive shaft
of the drilling head and has radial dimensions which in particular are greater than
or equal to the external dimensions of the foundation element. The earth which has
been drilled out can then be discharged to outside the foundation element in a suitable
way. It has been found that the foundation element can therefore be introduced into
the ground relatively easily and that considerable penetration depths of more than
66 metres can be achieved without a heavy press installation, pile-driving device,
vibratory unit or the like being required directly for that purpose. The method can
advantageously be used at working locations where only a low working height is available.
The minimum working space height required is in this case substantially determined
by the length of the foundation elements to be introduced. In this context, it is
advantageously possible to use a plurality of segments which can be joined to one
another and together serve to form one foundation element and which, by way of example,
are in each case welded to one another.
[0010] Earth which is drilled out by the excavating member passes via introduction openings
into a flushing chamber which is delimited by housing walls of the drilling head and
is located above the excavating member. The earth which has been drilled out is in
this case forced continuously into the flushing chamber via the introduction openings
by the excavating member and the drilling head which moves downwards together with
the foundation element. A stream of liquid supplied via a feed line is passed through
the flushing chamber. In this way, the earth which has been released can mix with
the flushing liquid in the flushing chamber and can easily be discharged via a discharge
line. In this case, it is possible for the flushing liquid together with the earth
which has been drilled out to be discharged via a suitable system of lines to well
away from the immediate working location, for example to a sludge repository. Making
use of a flushing chamber of this type has demonstrated that water, for example water
from a lake or river in the vicinity, without further additives for increasing the
viscosity, can be used very effectively as a flushing liquid. Furthermore, it is advantageous
that the discharge of the earth which has been drilled out does not have to lead to
contamination of the remainder of the drilling head, of the cavity in the foundation
element and of the working area above the ground.
[0011] It is noted that
US-A-4406498 discloses a shield tunnelling machine having a combination of a cutter head and a
muck chamber. This machine is used for excavating tunnels and not for forming foundation
piles.
[0012] According to the present invention the pressure of the flushing liquid fed into the
flushing chamber is preferably set to a slight excess pressure with respect to a prevailing
groundwater pressure in the surrounding ground. In particular, the excess pressure
is in this case approximately 0.1-0.3 bar. This excess pressure ensures that the ground
can be discharged in a controlled manner at the location of the excavating member.
This reduces the risk of undesirable disturbances to the surrounding ground, and therefore
also the risk of erosion and subsidence. The rate at which the earth mixture is discharged
can be accurately matched to the desired penetration rate as a result of the use of
the flushing chamber with a slight excess pressure.
[0013] The introduction openings are advantageously provided in a base plate which delimits
the flushing chamber on the underside and is fixed to the housing in such a manner
that it can move up and down in a controllable manner in the drilling head. If a fault
is detected which is related to an accumulation of pieces of earth which are too large
for the introduction openings, this fault can be overcome by, as it were, breaking
up the pieces of earth between the base plate and excavating member by means of the
base plate being moved downwards with a certain force.
[0014] In a first, more particular preferred embodiment, the progress of introducing the
foundation element into the ground is monitored and, in the event of a deviation from
the intended direction of introduction of the foundation element being observed, the
position of the drive shaft with excavating member is adjusted accordingly with respect
to the bottom part of the foundation element. The adjustment may involve displacement
of the drive shaft with excavating member in the horizontal plane and/or tilting of
the drive shaft with excavating member with respect to the vertical. The new position
leads to the excavating member starting to dig out more earth on one side and less
earth on the other side beneath the bottom part of the foundation element. As a result,
the foundation element is subject to less resistance on one side and more resistance
on the other side as it penetrates into the earth, and will begin to straighten itself
out. This possibility of controlling the drilling head advantageously allows the intended
direction of introduction to be monitored in a reliable way and adjusted if desired.
[0015] This form of control works well in particular in combination with a foundation element
of which the bottom part is provided with a tapering peripheral wall part. Moreover,
the tapering peripheral wall part reduces the initial resistance to penetration by
the foundation element.
[0016] In a second, more particular preferred embodiment, during the introduction into the
ground, a downward force is exerted on the foundation element with the aid of a press
installation. The press installation is in this case of the hydraulic type which comprises
a frame which is supported on the ground next to the foundation element. The frame
can be anchored to the ground by means of anchoring elements, for example threaded
anchors, but may also be held against the ground with the aid of counterweights. As
a result, the foundation element can be pressed uniformly into the ground, with simultaneous
driving of the drilling head, by means of a relatively light press installation, without
the surrounding area being adversely affected. The press installation may advantageously
be designed with a limited overall height, in particular a height of less than 3 metres,
and generates little noise and is free of vibrations. Moreover, it is safe for workers
on the construction site.
[0017] The required introduction force can be reduced further by filling the cavity in the
foundation element with liquid while it is being introduced into the ground.
[0018] The press installation is provided with engagement means which can be moved up and
down by hydraulic means with respect to the frame. The engagement means are preferably
also laterally adjustable. This makes it possible to adjust the direction in which
the foundation element is introduced slightly if desired. This is important in particular
when the bottom part of the foundation element starts to be introduced into the ground,
since the above-described adjustment with the aid of the drilling head is at that
stage not yet fully functional.
[0019] In a more particular, third preferred embodiment, the drilling head is designed in
such a manner that the excavating member can be retracted with respect to the drive
shaft substantially in a plane which is perpendicular to the direction of introduction,
into an at-rest position, in which the maximum dimension of the entire drilling head
is then smaller than internal dimensions of the cavity in the foundation element.
The direction of movement of the excavating member in the plane which is substantially
perpendicular to the drilling direction advantageously ensures that the drilling head
can be used immediately as soon as the excavating member emerges beneath the foundation
element. This also allows improved control of the drilling head. After the foundation
element has been sunk or in the event of problems in the meantime, the drilling head
can, then be retracted upwards through the cavity. As a result, the drilling head
is not lost and can in each case be re-used and/or repaired. It is also possible for
the drilling head to be temporarily retracted in order for impenetrable obstacles
which it may encounter to be removed by other means before drilling is then recommenced.
[0020] In a variant, the excavating member is provided with a part which can be folded down.
This fold-down part preferably extends from the free end of the excavating member
to just inside the internal dimensions of the cavity in the foundation element. The
fold-down part can then be folded out during the first revolution of the excavating
member about the drive shaft and/or folded in prior to or during the retraction of
the drilling head in the upwards direction through the foundation element.
[0021] At the same time as the drilling head is being drawn upwards, it is possible for
a settable material to be injected into the foundation element. In this way, a strong,
robust foundation pile, which is surrounded by the foundation element is formed. It
is also possible for the drilling head and the foundation element which has been sunk
to depth to be removed into the upwards direction substantially together, while, at
the same time, a settable material is being injected into the cavity left behind.
In this case too, a reliable, robust foundation pile is advantageously formed. After
the material has set, this pile then consists exclusively of set injected material.
It is then possible to re-use not just the drilling head but also the foundation element
itself.
[0022] In another variant, the foundation element is left in the ground and, after the drilling
head has been removed, is at least partially filled with foundation material. If necessary,
the foundation element can be filled with liquid, for example a bentonite-containing
liquid, in an intermediate step. This prevents the foundation element from undesirably
filling up with earth or contaminated groundwater. The foundation material used can
then once again be a settable material, but also, for example, a foundation material
which is tipped in as a loose material, such as earth or rocks. In the event of the
foundation element being partially filled with rocks, it has proven advantageous for
the foundation element to be provided, at least in its bottom wall part, with a profile,
such as ribs.
[0023] The above-mentioned method makes it possible to form both free-standing foundation
piles and deep walls (bored pile walls) which comprise a plurality of foundation elements
which have been formed in accordance with the invention.
[0024] When the deep walls are being used, the foundation elements can be fitted such that
they adjoin one another and also such that a space is left between them, in which,
for example, sealing bodies can be arranged. The sealing bodies can then be forced
into the ground using the same press installation. Drilling has not proven necessary
for this operation.
[0025] In particular, the tubes are provided on the outer side with connecting pieces which
extend in the longitudinal direction. It is then possible for the sealing bodies,
such as sheet pile planks, to be arranged between the connecting pieces. The result
is a combination deep wall, comprising hollow foundation elements and sheet pile planks
with reliable properties such as water tightness and strength. The provision of a
connecting piece on the outer side of the foundation element is advantageously possible
through the fact that the foundation element is introduced into the ground in a substantially
upright position without having to be rotated about its longitudinal axis. After all,
in the event of rotation, a connecting piece of this type would present considerable
additional resistance. The sheet pile planks can be coupled to the foundation elements
in segments which can be connected to one another.
[0026] More particularly, the foundation elements are in this case provided with a profiled
connecting piece which is designed to engage on a profiled edge part of the sealing
body by means of a sliding movement in the abovementioned longitudinal direction.
[0027] Further preferred embodiments of the invention are defined in the subclaims.
[0028] The invention also relates to a system for using the method according to one of claims
16-41.
[0029] The invention will be explained in more detail with reference to the appended drawing,
in which:
Fig. 1-4 diagrammatically depict successive method steps in a method according to
claim 1;
Fig. 5 shows a cross-sectional view on line V-V in Fig. 4;
Fig. 6 shows a view, on an enlarged scale, of details X, Y and Z from Fig. 5;
Fig. 7 shows a cross-sectional view through an embodiment of a drilling head which
is positioned in a segment of a foundation element, suitable for using in the method
of claim 1;
Fig. 8 shows a view from below of Fig. 7 with excavating members positioned in a drilling
position;
Fig. 9 shows a view corresponding to that shown in Fig. 8, with excavating members
positioned in an at-rest position;
Fig. 10 shows a diagrammatic cross-sectional view through a system with an anchored
press installation;
Fig. 11 shows a transverse sectional view of Fig. 10;
Fig. 12 shows a view corresponding to that shown in Fig. 10 during the placing of
the foundation element;
Fig. 13 shows a view corresponding to Fig. 10 during the retraction of the drilling
head;
Fig. 14 shows a view corresponding to that shown in Fig. 10 with a plurality of foundation
piles formed next to one another;
Fig. 15a-f shows six steps involved in forming a deep wall with overlapping piles;
Fig 16 shows a cross section through a variant of a deep wall which has been formed;
Fig. 17 shows a perspective view of a variant of a drilling head positioned in a bottom
part of a foundation element, in a system according to claim 16;
Fig. 18 shows a view corresponding to that shown in Fig. 17, seen more from above;
Fig. 19 shows a diagrammatic longitudinal section through Fig. 17 with laterally adjusted
excavating members;
Fig. 20 shows a view of Fig. 19 from below;
Fig. 21 shows a diagrammatic longitudinal section view of a further variant; in a
system according to claim 16 and
Fig. 22 shows a cross section on line XXII-XXII in Fig. 21.
[0030] It can be seen from Fig. 1 how a hollow tube 1 has been positioned in a hydraulic
press device 2 and is ready to be forced into the ground as a foundation element.
A drilling head 3 is arranged in a bottom part of the tube 1. The drilling head 3
has an external diameter which is less than or equal to the internal diameter of the
tube 1. During operation, the hydraulic press device 2 and the drilling head 3 are
driven simultaneously, i.e. the drilling head 3 drills out earth which the front part
of the tube 1 meets at the same time as the tube 1 is advancing (Fig. 2). The drilling
head 3 is equipped with a flushing section. During the drilling, the earth which has
been drilled out is discharged by means of a flow of water which is passed through
the flushing section. The flow of water is in this case controlled in such a manner
that there is never too much earth discharged. The flow of water together with the
earth which is released is tipped into a sludge repository at a distance from the
working location.
[0031] The drilling head 3 is advantageously provided with a control system making it possible
to correct any deviations in the penetration direction during drilling.
[0032] After the tube 1 has been sunk (Fig. 3), the drilling head 3 is retracted upwards
through the tube 1. Before the drilling head 3 is retracted, the tube 1 can be filled
with water, so that it is impossible for any earth to enter from the underside. After
the drilling head 3 has been retracted, the tubes 1 can be filled with earth, concrete
or the like.
[0033] An injection line is advantageously carried along during the operation of forcing
the tube into the ground. The injection line can be used to add lubricant around the
tube 1 in order to further reduce the friction. The lubricant may, for example, comprise
bentonite lubrication. The lubrication can also be used to make it possible to carry
out corrections to the penetration direction of the tube 1.
[0034] After a number of tubes 1 have been put in place, a sheet pile plank 4 is pressed
between the tubes 1 (Fig. 4). The same press device 2 can be used for this purpose.
Suitably profiled connecting pieces 6 have been welded, bolted or connected in some
other way to the tubes 1 beforehand to match the sheet pile planks 4 (Fig. 6), and
longitudinal edges 7 with a complementary profile of the sheet pile planks 4 can be
pushed into these connecting pieces.
[0035] After the sheet pile planks 4 have been sunk, the abovementioned injection pipes
can be used to deliver a settable material, for example a grout mixture. As a result
of a material of this type being pressed in from the underside of the tubes 1, firstly
the tubes 1 are bonded to the earth and secondly the connecting pieces 6 and the longitudinal
edges 7 of the sheet pile planks 4 are also provided with a cladding. This cladding
enhances the water barrier function.
[0036] To enable further absorption of compressive forces on the deep wall, it is also possible
to fit tie rod anchors. The tie rod anchors are advantageously formed by threaded
injection anchors. The tie rod anchors can be positioned, for example, from the space
inside the hollow tubes 1.
[0037] If the tubes 1 are to extend over great depths and/or if it is necessary to work
from a working space with a limited working height available, it is advantageously
possible to select to use tube segments which can be connected to one another. In
each case after a tube segment has been sunk into the ground using the internal drilling,
a subsequent tube segment is attached to the top of it, for example by welding. The
combined pressing and drilling process can then be continued until this tube segment
too has been sunk. In this case, it is advantageously possible to alternate between
two tubes. Components of the installation which are not in use while a new tube segment
is being connected to a first tube, for example a drive unit for the drilling head,
can then be transferred to another tube and drive the drilling head located there
during the pressing operation. In this way, various components can be utilized efficiently,
and in particular the time required to join the tube segments to one another is optimally
utilized.
[0038] The method is suitable in particular for placing tubes with a relatively large cross
section, in particular larger than one and a half metres, in the ground. The tube
is composed in particular of tube segments with a height of approximately two metres.
[0039] Before the tube or a first tube segment of the tube is pressed into the ground, it
is preferable first of all for a housing of approximately one metre to be pressed
into the ground. This housing is used to prevent material from being flushed out during
the initial part of the drilling and pressing process.
[0040] In Fig. 7, a drilling head 9 comprises a rotatable excavator wheel with adjustable
excavating members 10. Above the excavator wheel there is a flushing chamber 11 with
rock crusher. The flushing chamber 11 is connected to flushing lines 13. Furthermore,
the drilling head 9 comprises a hydraulic drive 12 for rotating the excavator wheel
during introduction of a tube segment 14. Controllable clamping means 15 with seals
16 which engage in a sealing manner with the inner peripheral wall of the tube segment
14 are provided along the peripheral wall of the drilling head 9. With the aid of
control cylinders 17, the drilling head 9 can be accurately oriented with respect
to the tube segment 14 during the introduction operation. With this, a part of the
drilling head 9 in which the excavator wheel with excavating members 10 and a drive
shaft of the excavator wheel are mounted tilts.
[0041] A downwardly tapering peripheral wall part 18, which merges into a cylindrical part
19, is provided on the outer peripheral wall of the tube segment 14. The cylindrical
part 19 forms an overlap with respect to that part of the outer peripheral wall of
the tube segment 14 which is located above it. The overlap has the advantage that
during the advancing movement space is left clear behind it. This space can advantageously
be used for the abovementioned supply of lubricant along the outer peripheral wall
of the foundation element. For this purpose, the overlap is preferably a few centimetres.
The space can also be used to supply a particularly slow-setting material which, after
it has set, bonds the earth to the foundation element. In the case of a combination,
in a first phase of penetration a lubricant is supplied, and in a second phase, after
the foundation element starts to approach or has reached its final depth, this lubricant
is expelled by the settable material, in particular cement.
[0042] The excavating members 10 can be displaced in the radial direction between a drilling
position (Figs. 7 and 8) and an at-rest position (Fig. 9). In the drilling position,
the excavating members 10 extend beyond the outer peripheral wall of the tube segment
14. In the at-rest position, the drilling head 9 as a whole has a cross-sectional
dimension which is smaller than the inner peripheral wall of the tube segment 14.
[0043] In Figs. 10 and 11, the drilling head 9, together with the first tube segment 14
from Fig. 7 are positioned beneath a press installation 20. The press installation
20 comprises a frame which is anchored to the ground 22 by anchors 21. The installation
20 comprises a hydraulic press section 24 which is designed to engage on the tube
segment 14 and to press it downwards into the ground 22 with the excavator wheel of
the drilling head 9 being driven.
[0044] Fig. 12 shows a number of steps further in the drilling introduction of the tube,
in which a plurality of tube segments 14, which are connected to one another, have
already been pressed into the ground with, at the same time, the earth located beneath
the front part of the tube segment 14 which was introduced first being drilled out
at the same time. This procedure can be continued until a desired depth has been reached.
The press section 24 is in this case in a raised position, so that a new tube segment
can be placed beneath it.
[0045] Fig. 13 shows a tube which has been sunk and in which the drilling head 9 is being
removed upwards through the interior of the tube. The tube which is being introduced
in this way can already form a foundation pile. It is preferable for the tube to be
at least partially filled with foundation material, in particular settable material.
[0046] Fig. 14 shows the situation in which a plurality of filled foundation piles 26 of
this type have been formed next to one another beneath the press installation 20.
It is clearly apparent that the press section 24 can be displaced sideways along the
frame, so that the plurality of piles 26 can be formed in succession without the installation
20 having to be moved along every time.
[0047] As a result of the piles adjoining one another, it is advantageously possible to
form a deep wall. They can be made to adjoin one another with separate sealing elements
positioned between them, as in Fig. 1-6, but it is also possible to have the piles
adjoining one another with a slight overlap. Fig. 15a-f show a preferred method for
forming a deep wall in this way. First of all, tubes 30 are introduced into the ground
at positions 1, 2 and 3 (Fig. 15a). Then, with simultaneous injection of settable
material 31 into the tubular cavity which has been released, they are pulled back
out of the ground together with the used drilling head (Fig. 15b). Reinforcing bars
32 are arranged in the as yet unset material 31 (Fig. 15c). Then, tubes 34 are introduced
into the ground at the intervening, positions 4, 5 and 6. During the introduction,
the drilling head drills out a small proportion of the piles 35 which have been formed
previously (Fig. 15d). The tubes 34 are then also, with simultaneous injection of
settable material 36 into the tubular cavity released, pulled back out of the ground
together with the used drilling head (Fig. 15e). Reinforcing bars 37 are placed in
the as yet unset material 36 (Fig. 15f). This forms a very strong deep wall, of which
the piles which have been formed in accordance with the invention adjoin one another
in a reliably watertight and successful way. The material 36 can bond to the previously
injected material 31 very well during the injection, while the reinforcing bars 32,
37 contribute to the rigidity and strength of the deep wall.
[0048] Fig. 16 shows a deep wall of which the tubes 40 are arranged in a zigzag shape. This
contributes to a further reinforcement of the deep wall and can advantageously be
produced using the method according to the invention.
[0049] Fig. 17-20 show a variant of a bottom part or segment of a tubular foundation element
50. This includes upper and lower positioning lugs 51 as well as a clamping wall part
52 which is set back inwards. The outer peripheral wall comprises a downwardly tapering
peripheral wall part 53 which at the top merges into a cylindrical wall part 54 with
a thickness which is greater than that of the part of the outer peripheral wall of
the foundation element 50 which is located above it.
[0050] A drilling head 55 has been lowered into the inside of the foundation element 50.
In the process, the drilling head 55 is automatically centred between the positioning
lugs 51. An upper edge 56 of the clamping wall part 52 is in this case used as a stop
edge for delimiting the drilling head 55 downwardly.
[0051] The drilling head 55 comprises controllable clamping means 60 which clamp securely
on to the clamping wall part 52. In this case, the clamping means 60 are formed by
inflatable strips. These have the advantage of simultaneously clamping and forming
a seal. Connection nozzles 61 for the clamping means 60, which are intended to be
connected to pneumatic or hydraulic control lines are provided in the drilling head
55.
[0052] In the drilling head 55 there is a plate 62 which is fixedly connected to an outer
peripheral wall 63 of the drilling head 55. Above this plate 62 there is a mounting
flange 64 on which a drive 65 is mounted for driving an excavator wheel with excavating
members 71 which is mounted on a drive shaft 70 (the excavator wheel with excavating
members is only shown in Figs. 19 and 20). The drive 65 is in this case formed by
a plurality of hydraulic motors which engage on the drive shaft 70 by means of planetary
gear mechanisms. The hydraulic motors have the advantage of taking up little space
and being able to supply a high power while not being sensitive to dirt and moisture.
The hydraulic motors are provided on their top sides with openings which are intended
to be connected to hydraulic supply lines. A plurality of control members 74 are distributed
over the periphery between the plate 62 and the mounting flange 64 and are in this
case formed by actuable cylinders. The control members 74 are provided with connection
nozzles to be connected to pneumatic or hydraulic control lines and are designed to
adjust the position of the drive shaft 70 with respect to the tapering peripheral
wall part 53 of the foundation element 50 in the plane which is perpendicular to the
drive shaft 70. Figs. 19 and 20 show a position in which the drive shaft 70 with drive
members 71 has been displaced a few centimetres to the left from the centre. As a
result, the penetration direction of the bottom part of the foundation element 50
will turn slightly to the right during further movement.
[0053] The control members 74 may be actuated manually or in automated fashion; it is preferable
to use measuring means to determine the direction of advance of the foundation element
50. The measuring means may be provided in or on the drilling head and/or may interact
therewith and are formed, for example, by inclinometers in the drilling head or a
laser beam which interacts with a sight or a plumb-line whose position is determined.
The plumb-line may advantageously also serve as a proximity sensor and/or a velocity-measuring
device.
[0054] Beneath the plate 62 there is a base plate 78 which is provided with a large number
of introduction openings 79. A flushing chamber 80 is delimited between the two plates
62, 78. A feed line 81 for supplying a flushing liquid under a slight excess pressure
and a discharge line 82 are connected to the flushing chamber 80. While earth is being
drilled out by the excavating members 71 and, at the same time, the drilling head
55 is advancing downwards into the ground together with the foundation element 50,
the earth which is drilled out is automatically forced into the flushing chamber 80
via the introduction openings 79. There, the earth mixes with the flushing liquid,
and this mixture is guided up out of the foundation element 50 via the discharge line
82. The flushing liquid enters the flushing chamber 80 via the feed line 81, comes
into contact with the base plate 78 and then sprays up on all sides. The turbulence
which results advantageously ensures intimate mixing of the flushing liquid and the
earth.
[0055] The introduction openings 79 are preferably designed in such a manner that they widen
towards the top. As a result earth which enters the introduction openings will relief
by the time it enters the flushing chamber 80.
[0056] A plurality of displacement members 84, which in this case are formed by actuable
cylinders, are provided distributed over the periphery between the plate 62 and the
base plate 78. The displacement members 84 are provided with connection nozzles for
connection to pneumatic or hydraulic control lines and are designed to be able to
move the base plate 78 up and down in the axial direction in the direction of the
excavating members 71. In this way, it is possible to execute a type of crushing movement
if a blockage occurs between the excavating members 71 and the base plate 78.
[0057] It is possible to switch the feed and discharge lines in terms of their functions
in order to flush blockages out of the flushing chamber 80. This switching may advantageously
take place above ground outside the foundation element 50. Furthermore, a bypass 90,
in which there is an actuable valve, is also provided between the feed line 81 and
the discharge line 82. Actuable valves are also accommodated in the feed and discharge
lines 81, 82. The lines can be flushed efficiently by actuating these valves in a
suitable way.
[0058] Fig. 21 and 22 show another variant, in which a bottom part of a foundation element
is composed of a section 100 which is, or can be, fixedly connected to the other part
of the foundation element and a section 101 which is movably connected to this section
100. In this case, the section 101 is connected to the section 100, which is of slightly
smaller dimensions, by means of chains 102, and the section 101 is of double-walled
design. In the sections there is secured a drilling head, of which excavating members
106, which are mounted on a excavator wheel in such a manner that they can be folded
over, protect beneath the section 101. The drilling head comprises an upper part 107,
which is pivotably connected, in a manner which can be controlled by means of control
members 108, to a lower part 109. The drilling head part 107 is in this case accommodated
in a sealing manner in the section 100 while the drilling head part 109 is accommodated
in the section 101. This creates a control option by suitable actuation of the control
members 108. The position of the drilling head part 109 with a drive shaft with the
excavator wheel and the excavating members 106 inside it can be adjusted with respect
to the drilling head part 107 and as a result with respect to the section 100 of the
foundation element. During further drilling introduction, the section 100 will, as
it were, be pulled along behind the adjusted section 101.
[0059] The drilling head part 109 in this case comprises an electric drive 110 for driving
the excavator wheel with excavating members 106. A flushing chamber 112, in which
a flushing line 113 opens out, is diagrammatically indicated above the excavator wheel
with excavating members 106. Furthermore, there is a direction indicator with a camera
115 directed at it, the direction indicator acting between the two drilling head parts
107, 109. To provide improved visibility, lighting may be provided in the drilling
head. An injection line 116 for supplying filling medium, lubricant and/or foundation
material is mounted on the outer side of the drilling head.
[0060] The drilling head part 107 may extend to above the ground and if desired may in each
case be lengthened at the same time as the foundation element. In this way, the inner
side of the drilling head can be kept dry, which is important in particular for the
drive and the measuring means. During operation, liquid can be placed between the
drilling head part 107 and the section 100, in order to offer a counterpressure to
the groundwater pressure.
[0061] In addition to the embodiments described above, numerous variants are possible and/or
it is possible to produce combinations between the embodiments, while staying in the
scope of the claims. In addition to tubular foundation elements it is also possible
to introduce other forms of foundation elements provided with a cavity. The foundation
elements may also comprise two or more longitudinal parts which adjoin one another.
This has the advantage that these longitudinal parts can each be placed around the
feed and control lines without the latter having to be uncoupled. As an alternative
to sheet pile planks, it is also possible for complete bodies made from a settable
material, for example a grout material, to be fitted between the foundation elements
by means of injection. As an alternative to being welded to one another, the segments
may also be coupled to one another in other ways. It is also possible for the foundation
elements themselves to be provided with suitably profiled shaped connecting pieces
which are designed to be received slideably in complementary connecting pieces on
foundation elements which have already been put in place. As an alternative to a separate
base plate, the flushing chamber may also be delimited on the underside by a excavator
wheel provided with introduction openings and/or by the rotating excavating members
themselves.
[0062] During introduction of a foundation element, the majority of the drilling head is
preferably located inside the bottom part of the foundation element. It is preferable
for only parts of the drive shaft and the excavating members to be located beneath
the foundation element. Since the drilling head can be clamped securely into the foundation
element and is provided with its own drive unit, the drilling head can advantageously
be kept very compact, in particular with a height of less than approximately two metres.
The compact drilling head merely has to be powered and/or actuated via preferably
flexible lines. This ensures that the drilling head can be removed again from a foundation
element which has been put in place even in small working spaces with a limited available
height. Furthermore, the drilling head is provided with significant protection against
damage from the outside, and accurate positioning and control are possible without
having to use rigid connecting and drive means which have to extend above ground.
[0063] Therefore, the invention creates an efficient and reliable method and a system for
carrying out a method of this type which can highly advantageously be used for difficult
projects, for example in the vicinity of fragile constructions, such as a building
of historic value, or from limited working spaces, for example from an existing tunnel
below the ground, in which case the possibility of counteracting the prevailing water
pressure counts as an additional benefit.
1. Method for forming at least on foundation pile or deep wall in the ground, comprising
the step of sinking one or more hollow foundation elements (1, 14, 30, 50) into the
ground with a substantially vertical orientation, in which the sinking of the hollow
foundation element (50) into the ground takes place during driving of a removable
drilling head (3, 9, 55) which drilling head (55), during the sinking of the foundation
element (50), is in a drilling position in which the drilling head (55) extends at
least partially below a bottom part of the foundation element (50) by means of at
least one excavating member (10, 71) which rotates about a drive shaft (70) and has
radial dimensions which are in particular greater than or equal to external dimensions
of the foundation element (50), in which the excavating member (71), at the same time
as the foundation element (50) is being sunk, drills out earth beneath the said bottom
part of the foundation element (50), and in which at least the drilling head (55),
after the foundation element (50) has been sunk, is removed again from the ground,
characterized in that
earth which is drilled out by the excavating member (71) passes, via introduction
openings (79) into a flushing chamber (80), which is located above the excavating
member (71), where it is mixed with a flushing liquid, which is introduced into the
flushing chamber (80) under pressure via at least one feed line (81), before then
being discharged upwards to outside the foundation element (50), together with the
flushing liquid, via at least one discharge line (82).
2. Method according to claim 1, in which the pressure of the flushing liquid supplied
is set to a value which is higher than the groundwater pressure prevailing in the
surrounding ground, in particular an excess pressure of approximately 0.1-0.3 bar.
3. Method according to claim 1 or 2, in which a base plate (78), which is provided with
the introduction openings (79) and delimits the underside of the flushing chamber
(80), is moved substantially up and down in the direction of the excavating member
(71) in the event of a problem being detected.
4. Method according to one of the preceding claims, in which, if the foundation element
(50), while it is being sunk, starts to deviate from the intended direction of introduction,
the position of at least the drive shaft (70), together with the excavating member
(71) of the drilling head (55) is adjusted with respect to the foundation element
(50).
5. Method according to one of the preceding claims, in which, during the sinking of the
foundation element (1), a downwardly directed compressive force is exerted on the
foundation element (1), with the aid of a pressing installation (2) which is supported
on the ground by means of a frame and in particular is anchored to the ground.
6. Method according to one of the preceding claims, in which the drilling head (55),
while the foundation element (50) is being sunk, is positioned in such a manner with
respect to the foundation element (50) that the drilling head (55) is located partly
inside the foundation element (50), while the remaining part is located below the
bottom part of the foundation element (50).
7. Method according to claim 6, in which the drilling head (55), during the drilling,
is fixed to an inner peripheral wall part (52) of the bottom part of the foundation
element (50) with the aid of controllable clamping means (60).
8. Method according to one of the preceding claims, in which the excavating member (10)
can be displaced with respect to the drive shaft, substantially in a plane which is
perpendicular to the direction of introduction, and after the foundation element (14)
has been sunk, the excavating member (10) is moved from the drilling position into
an at-rest position, in which the excavating member (10) has radial dimensions which
are smaller than internal dimensions of the foundation element (14), after which the
drilling head (9) is retracted upwards through the interior of the foundation element
(14).
9. Method according to one of the preceding claims, in which, before the drilling head
(3) is retracted upwards, the foundation element (1) is filled with liquid.
10. Method according to one of the preceding claims, in which, after the drilling head
(9) has been retracted, the foundation element (14) is at least partially filled with
a foundation material (26).
11. Method according to one of the preceding claims, in which, after the foundation element
(30) has been sunk, the drilling head and/or the foundation element (30) are pulled
back upwards, with simultaneous injection of a foundation material (31), in particular
a settable foundation material.
12. Method according to one of the preceding claims, in which, during the sinking operation,
one or more injection lines are entrained for the purpose of supplying foundation
material after the foundation element has been sunk.
13. Method according to one of the preceding claims, in which, during the sinking operation,
one or more injection lines are entrained for the purpose of supplying lubricant around
the foundation element while it is being introduced into the ground.
14. Method according to one of the preceding claims, in which each foundation element
(1) is composed of segments, in particular with a height of less than 2 metres, which
can be joined to one another, in particular by welding.
15. Method according to one of the preceding claims, in which the foundation element,
in the section above the drilling head, while it is being sunk is filled with liquid,
in particular water.
16. System in particular for using the method according to one of claims 1-15, comprising:
- at least one hollow foundation element (50);
- an installation (2) designed to exert a substantially vertically oriented force
on the foundation element (50); and
- a drilling head (55) which can be lowered into the foundation element and has at
least one excavating member which can rotate about a drive shaft and, in a drilling
position, while the foundation element (50) is being sunk into the ground, has radial
dimensions which in particular are greater than or equal to external dimensions of
the foundation element (50),
characterized in that,
the drilling head (55) comprises a flushing chamber (80), which is located above the
excavating member (71) and on the underside comprises introduction openings (79) provided
in particular in a base plate (78), to which flushing chamber (80) at least one feed
line (81) for introducing a flushing liquid into the flushing chamber (80) under pressure
is connected, and to which flushing chamber at least one discharge line (82) for discharging
the flushing liquid mixed with earth which has been drilled out from the flushing
chamber (80).
17. System according to claim 16, in which the introduction openings (79) widen in the
upwards direction.
18. System according to claim 16 or 17, in which displacement members (84) are provided
in the drilling head (55) for moving the base plate (78) substantially up and down
in the direction of the excavating member (71).
19. System according to claim 18, in which the displacement members (84) comprise hydraulically
actuable displacement cylinders.
20. System according to claim 18 or 19, in which the displacement members (84) act between
the base plate (78) and a housing part (62) of the drilling head (55), which, during
drilling, can be fixed in position with respect to the foundation element (50).
21. System according to one of claims 16-20, in which control members (74) are provided
in the drilling head (55) for adjusting the position of the drive shaft (70) with
the excavating member (71) with respect to a bottom part of the foundation element
(50).
22. System according to claim 21, in which the control members (74) comprise hydraulically
actuable control cylinders.
23. System according to claim 21 or 22, in which the control members (74) are active between
a mounting flange (64) in which the drive shaft (70) is mounted and a housing part
(62) of the drilling head (55), which, during drilling, can be fixed in position with
respect to the bottom part of the foundation element (55).
24. System according to one of claims 21-23, in which the control members (74) act so
as to adjust the position of the drive shaft (70) together with the excavating member
(71) with respect to the bottom part of the foundation element (55) in a direction
which is substantially perpendicular to the drive shaft (70).
25. System according to one of claims 21-23, in which the control members (74) act so
as to tilt the angular position of the drive shaft together with the excavating member
(71) with respect to the bottom part of the foundation element (50).
26. System according to one of claims 16-25, in which the bottom part of the foundation
element (55) is provided with a downwardly tapering peripheral wall part (53).
27. System according to one of claims 16-26, in which there are measuring means for determining
the direction of introduction of the foundation element, which measuring means interact
with and/or are provided on the drilling head.
28. System according to one of claims 16-27, in which the drilling head (55) incorporates
a drive unit (65) for driving the drive shaft (70), in particular a hydraulic motor.
29. System according to claim 28, in which planetary gear mechanisms are provided as transmission
between the drive unit (65) and the drive shaft (70).
30. System according to one of claims 16-29, in which the installation is a press installation
(20) which comprises a frame which can be supported on the ground, in particular can
be anchored to the ground, and which is provided with engagement means, which can
move up and down by hydraulic means with respect to the frame, for exerting a downwardly
directed compressive force on the foundation element (50).
31. System according to claim 30, in which the engagement means can also be controllably
adjusted with respect to the frame in a direction which is substantially perpendicular
to the downward pressing direction.
32. System according to one of claims 16-31, in which the drilling head (55) comprises
controllable clamping means (60) for clamping it securely on to an inner peripheral
wall part (52) of a bottom part of the foundation element (50).
33. System according to one of claims 16-32, in which a bottom part of the foundation
element (50) is provided, along its inner peripheral wall, with a stop edge (56) for
delimiting the drilling head (55) downwardly.
34. System according to one of claims 16-33, in which a bottom part of the foundation
element (50) is provided, along its inner peripheral wall, with positioning lugs (51)
for positioning the drilling head (55).
35. System according to one of claims 16-34, in which the excavating member (71) can be
displaced with respect to the drive shaft substantially in a plane which is perpendicular
to the drive shaft, between the drilling position and an at-rest position in which
the excavating member (71) has radial dimensions which are smaller than internal dimensions
of the foundation element (50).
36. System according to one of claims 16-35, in which there are one or more injection
lines for supplying foundation material after the foundation element has been sunk.
37. System according to one of claims 16-36, in which there are one or more injection
lines for supplying lubricant around the foundation element while it is being introduced
into the ground.
38. System according to claim 37, in which the injection line opens out behind an overlap
in the peripheral wall of a bottom part of the foundation element.
39. System according to one of claims 16-38, in which each foundation element (50) comprises
segments, in particular with a height of less than 2 metres, and in which there are
means for connecting the segments to one another.
40. System according to claim 39, in which the drilling head (55) has a total height which
is less than the height of a segment of the foundation element (50).
41. System according to one of claims 16-40, in which the drilling head (55) has a total
height which is less than 2 metres.
1. Verfahren zum Bilden wenigstens eines Gründungspfahls oder einer Tiefwand in dem Boden,
umfassend den Schritt eines Versenkens eines hohlen Gründungselements oder mehrerer
hohler Gründungselemente (1, 14, 30, 50) in den Boden mit einer im Wesentlichen vertikalen
Ausrichtung, wobei das Versenken des hohlen Gründungselements (50) in den Boden während
eines Antreibens eines entfernbaren Bohrkopfes (3, 9, 55) stattfindet, wobei sich
der Bohrkopf (55) während des Versenkens des Gründungselements (50) in einer Bohrposition
befindet, in der sich der Bohrkopf (55) wenigstens teilweise unter einem unteren Teil
des Gründungselements (50) mittels wenigstens eines Aushubelements (10, 71) erstreckt,
das sich um eine Antriebswelle (70) dreht und radiale Abmessungen aufweist, die insbesondere
größer als die oder gleich den Außenabmessungen des Gründungselements (50) sind, wobei
das Aushubelement (71) gleichzeitig mit dem Versenken des Gründungselements (50) Erde
unterhalb des unteren Teils des Gründungselements (50) ausbohrt, und wobei wenigstens
der Bohrkopf (55) wieder aus dem Boden entfernt wird, nachdem das Gründungselement
(50) versenkt worden ist,
dadurch gekennzeichnet,
dass Erdreich, das von dem Aushubelement (71) ausgebohrt wird, über Einführöffnungen (79)
in eine Spülkammer (80), die über dem Aushubelement (71) angeordnet ist, gelangt,
wo es mit einer Spülflüssigkeit, die über wenigstens eine Zuführleitung (81) unter
Druck in die Spülkammer (80) eingeführt wird, vermischt wird, bevor es dann zusammen
mit der Spülflüssigkeit über wenigstens eine Abfuhrleitung (82) nach oben bis außerhalb
des Gründungselements (50) abgeführt wird.
2. Verfahren nach Anspruch 1, wobei der Druck der zugeführten Spülflüssigkeit auf einen
Wert gesetzt wird, der größer als der in dem umgebenden Boden vorherrschende Grundwasserdruck
ist, insbesondere auf einen Überdruck von näherungsweise 0,1-0,3 bar.
3. Verfahren nach Anspruch 1 oder 2, wobei eine Basisplatte (78), die mit den Einführöffnungen
(79) versehen ist und die Unterseite der Spülkammer (80) begrenzt, in dem Fall, dass
ein Problem erfasst wird, in der Richtung des Aushubelements (71) im Wesentlichen
nach oben und unten bewegt wird.
4. Verfahren nach einem der vorhergehenden Ansprüche, wobei, falls das Gründungselement
(50) während des Versenkens beginnt, von der beabsichtigten Einführrichtung abzuweichen,
die Position wenigstens der Antriebswelle (70) zusammen mit dem Aushubelement (71)
des Bohrkopfes (55) in Bezug auf das Gründungselement (50) eingestellt wird.
5. Verfahren nach einem der vorhergehenden Ansprüche, wobei während des Versenkens des
Gründungselements (1) mithilfe einer Druckvorrichtung (2), die mittels eines Rahmens
an dem Boden abgestützt und insbesondere an dem Boden verankert ist, eine nach unten
gerichtete Druckkraft auf das Gründungselement (1) ausgeübt wird.
6. Verfahren nach einem der vorhergehenden Ansprüche, wobei der Bohrkopf (55) während
des Versenkens des Gründungselements (50) derart in Bezug auf das Gründungselement
(50) positioniert wird, dass der Bohrkopf (55) teilweise in dem Gründungselement (50)
angeordnet ist, während der restliche Teil unter dem unteren Teil des Gründungselements
(50) angeordnet ist.
7. Verfahren nach Anspruch 6, wobei der Bohrkopf (55) während des Bohrens mithilfe steuerbarer
Klemmmittel (60) an einem inneren Umfangswandteil (52) des unteren Teils des Gründungselements
(50) befestigt wird.
8. Verfahren nach einem der vorhergehenden Ansprüche, wobei das Aushubelement (10) in
Bezug auf die Antriebswelle im Wesentlichen in einer Ebene, die senkrecht zu der Einführrichtung
ist, verschoben werden kann, und wobei, nachdem das Gründungselement (14) versenkt
worden ist, das Aushubelement (10) von der Bohrposition in eine Ruheposition bewegt
wird, in der das Aushubelement (10) radiale Abmessungen aufweist, die kleiner als
Innenabmessungen des Gründungselements (14) sind, wobei anschließend der Bohrkopf
(9) durch das Innere des Gründungselements (14) nach oben zurückgezogen wird.
9. Verfahren nach einem der vorhergehenden Ansprüche, wobei das Gründungselement (1)
mit einer Flüssigkeit gefüllt wird, bevor der Bohrkopf (3) nach oben zurückgezogen
wird.
10. Verfahren nach einem der vorhergehenden Ansprüche, wobei das Gründungselement (14)
wenigstens teilweise mit einem Gründungsmaterial (26) verfüllt wird, nachdem der Bohrkopf
(9) zurückgezogen worden ist.
11. Verfahren nach einem der vorhergehenden Ansprüche, wobei, nachdem das Gründungselement
(30) versenkt worden ist, der Bohrkopf und/oder das Gründungselement (30) zurück nach
oben gezogen werden, mit einer gleichzeitigen Einspritzung eines Gründungsmaterials
(31), insbesondere eines härtbaren Gründungsmaterials.
12. Verfahren nach einem der vorhergehenden Ansprüche, wobei während des Versenkvorgangs
eine oder mehrere Einspritzleitungen zu dem Zweck, Gründungsmaterial zuzuführen, nachdem
das Gründungselement versenkt wurde, mitgenommen werden.
13. Verfahren nach einem der vorhergehenden Ansprüche, wobei während des Versenkvorgangs
eine oder mehrere Einspritzleitungen zu dem Zweck, um das Grundelement herum Schmierstoff
zuzuführen, während dieses in den Boden eingeführt wird, mitgenommen werden.
14. Verfahren nach einem der vorhergehenden Ansprüche, wobei jedes Gründungselement (1)
aus Segmenten, insbesondere mit einer Höhe von weniger als 2 Metern, besteht, die
miteinander verbunden werden können, insbesondere durch Schweißen.
15. Verfahren nach einem der vorhergehenden Ansprüche, wobei das Gründungselement in dem
Abschnitt über dem Bohrkopf, während es versenkt wird, mit einer Flüssigkeit, insbesondere
mit Wasser, gefüllt ist.
16. System, insbesondere zur Verwendung des Verfahrens nach einem der Ansprüche 1-15,
umfassend:
- wenigstens ein hohles Gründungselement (50);
- eine Vorrichtung (2), die ausgestaltet ist, um eine im Wesentlichen vertikal gerichtete
Kraft auf das Gründungselement (50) auszuüben; und
- einen Bohrkopf (55), der in das Gründungselement gesenkt werden kann und wenigstens
ein Aushubelement aufweist, das um eine Antriebswelle rotieren kann und in einer Bohrposition,
während das Gründungselement (50) in den Boden versenkt wird, radiale Abmessungen
aufweist, die insbesondere größer als die oder gleich den Außenabmessungen des Gründungselements
(50) sind,
dadurch gekennzeichnet,
dass der Bohrkopf (55) eine Spülkammer (80) umfasst, die über dem Aushubelement (71) angeordnet
ist und an der Unterseite Einführöffnungen (79), die insbesondere in einer Basisplatte
(78) vorgesehen sind, umfasst, wobei mit der Spülkammer (80) wenigstens eine Zuführleitung
(81) verbunden ist zum Einführen einer Spülflüssigkeit in die Spülkammer (80) unter
Druck, und wobei wenigstens eine Abfuhrleitung (82) zum Abführen der mit ausgebohrtem
Erdreich vermischten Spülflüssigkeit aus der Spülkammer (80) mit der Spülkammer verbunden
ist.
17. System nach Anspruch 16, wobei sich die Einführöffnungen (79) in der Richtung nach
oben weiten.
18. System nach Anspruch 16 oder 17, wobei Verschiebeelemente (84) in dem Bohrkopf (55)
vorgesehen sind, um die Basisplatte (78) in der Richtung des Aushubelements (71) im
Wesentlichen nach oben und unten zu bewegen.
19. System nach Anspruch 18, wobei die Verschiebeelemente (84) hydraulisch betätigbare
Verschiebezylinder umfassen.
20. System nach Anspruch 18 oder 19, wobei die Verschiebeelemente (84) zwischen der Basisplatte
(78) und einem Gehäuseteil (62) des Bohrkopfes (55) wirken, der während des Bohrens
in einer Position in Bezug auf das Gründungselement (50) fixiert werden kann.
21. System nach einem der Ansprüche 16-20, wobei Steuerelemente (74) in dem Bohrkopf (55)
vorgesehen sind, um die Position der Antriebswelle (70) mit dem Aushubelement (71)
in Bezug auf einen unteren Teil des Gründungselements (50) einzustellen.
22. System nach Anspruch 21, wobei die Steuerelemente (74) hydraulisch betätigbare Steuerzylinder
umfassen.
23. System nach Anspruch 21 oder 22, wobei die Steuerelemente (74) zwischen einem Montageflansch
(64), in dem die Antriebswelle (70) montiert ist, und einem Gehäuseteil (62) des Bohrkopfes
(55) aktiv sind, der während des Bohrens in einer Position in Bezug auf den unteren
Teil des Gründungselements (50) fixiert werden kann.
24. System nach einem der Ansprüche 21-23, wobei die Steuerelemente (74) so wirken, dass
sie die Position der Antriebswelle (70) zusammen mit dem Aushubelement (71) in Bezug
auf den unteren Teil des Gründungselements (50) in einer Richtung einstellen, die
im Wesentlichen senkrecht zu der Antriebswelle (70) ist.
25. System nach einem der Ansprüche 21-23, wobei die Steuerelemente (74) so wirken, dass
sie die Winkelposition der Antriebswelle zusammen mit dem Aushubelement (71) in Bezug
auf den unteren Teil des Gründungselements (50) verkippen.
26. System nach einem der Ansprüche 16-25, wobei der untere Teil des Gründungselements
(50) mit einem sich nach unten verjüngenden Randwandteil (53) versehen ist.
27. System nach einem der Ansprüche 16-26, wobei Messmittel zum Bestimmen der Einführrichtung
des Gründungselements vorgesehen sind, wobei die Messmittel mit dem Bohrkopf zusammenwirken
und/oder an dem Bohrkopf vorgesehen sind.
28. System nach einem der Ansprüche 16-27, wobei der Bohrkopf (55) eine Antriebseinheit
(65) zum Antreiben der Antriebswelle (70), insbesondere einen hydraulischen Motor,
umfasst.
29. System nach Anspruch 28, wobei Planetengetriebemechanismen als Getriebe zwischen der
Antriebseinheit (65) und der Antriebswelle (70) vorgesehen sind.
30. System nach einem der Ansprüche 16-29, wobei die Vorrichtung eine Druckvorrichtung
(20) ist, die einen Rahmen umfasst, der an dem Boden abgestützt werden kann, der insbesondere
an dem Boden verankert werden kann, und die mit Kopplungsmitteln versehen ist, die
sich durch hydraulische Mittel in Bezug auf den Rahmen nach oben und unten bewegen
können, um eine nach unten gerichtete Druckkraft auf das Gründungselement (50) auszuüben.
31. System nach Anspruch 30, wobei die Kopplungsmittel weiterhin in Bezug auf den Rahmen
in einer Richtung, die im Wesentlichen senkrecht zu der Druckrichtung nach unten ist,
steuerbar eingestellt werden können.
32. System nach einem der Ansprüche 16-31, wobei der Bohrkopf (55) steuerbare Klemmmittel
(60) umfasst, um ihn sicher an einem inneren Umfangswandteil (52) eines unteren Teils
des Gründungselements (50) festzuklemmen.
33. System nach einem der Ansprüche 16-32, wobei ein unterer Teil des Gründungselements
(50) entlang seiner inneren unfangswand mit einer Anschlagkante (56) versehen ist,
um den Bohrkopf (55) nach unten zu begrenzen.
34. System nach einem der Ansprüche 16-33, wobei ein unterer Teil des Gründungselements
(50) entlang seiner inneren Umfangswand mit Positionieransätzen (51) zum Positionieren
des Bohrkopfes (55) versehen ist.
35. System nach einem der Ansprüche 16-34, wobei das Aushubelement (71) in Bezug auf die
Antriebswelle im Wesentlichen in einer Ebene, die senkrecht zu der Antriebswelle ist,
zwischen der Bohrposition und einer Ruheposition, in der das Aushubelement (71) radiale
Abmessungen aufweist, die kleiner als Innenabmessungen des Gründungselements (50)
sind, verschoben werden kann.
36. System nach einem der Ansprüche 16-35, wobei eine oder mehrere Einspritzleitungen
zum Zuführen von Gründungsmaterial, nachdem das Gründungselement versenkt worden ist,
vorgesehen sind.
37. System nach einem der Ansprüche 16-36, wobei eine oder mehrere Einspritzleitungen
zum Zuführen von Schmierstoff um das Gründungselement, während es in den Boden eingeführt
wird, vorgesehen sind.
38. System nach Anspruch 37, wobei sich die Einspritzleitung hinter einer Überdeckung
in der Randwand eines unteren Teils des Gründungselements nach außen öffnet.
39. System nach einem der Ansprüche 16-38, wobei jedes Gründungselement (50) Segmente,
insbesondere mit einer Höhe von weniger als 2 Metern, umfasst, und wobei Mittel zum
Verbinden der Segmente miteinander vorgesehen sind.
40. System nach Anspruch 39, wobei der Bohrkopf (55) eine Gesamthöhe aufweist, die kleiner
als die Höhe eines Segments des Gründungselements (50) ist.
41. System nach einem der Ansprüche 16-40, wobei der Bohrkopf (55) eine Gesamthöhe aufweist,
die kleiner als 2 Meter ist.
1. Procédé pour former au moins une pile de fondation ou mur profond dans le sol, comprenant
l'étape consistant à enfoncer un ou plusieurs éléments de fondation creux (1, 14,
30, 50) dans le sol avec une orientation sensiblement verticale, dans lequel l'enfoncement
de l'élément de fondation creux (50) dans le sol a lieu pendant l'entraînement d'une
tête de forage amovible (3, 9, 55), laquelle tête de forage (55) pendant l'enfoncement
de l'élément de fondation (50), est dans une position de forage dans laquelle la tête
de forage (55) s'étend au moins partiellement au-dessous d'une partie inférieure de
l'élément de fondation (50) au moyen d'au moins un élément d'excavation (10, 71) qui
tourne autour d'un arbre d'entraînement (70) et a des dimensions radiales qui sont
en particulier supérieures ou égales aux dimensions externes de l'élément de fondation
(50), dans lequel l'élément d'excavation (71), au moment où l'élément de fondation
(50) est enfoncé, fore la terre au-dessous de ladite partie inférieure de l'élément
de fondation (50), et dans lequel au moins la tête de forage (55), après que l'élément
de fondation (50) a été enfoncé, est à nouveau retirée du sol,
caractérisé en ce que :
la terre qui est forée par l'élément d'excavation (71) passe, via des ouvertures d'introduction
(79), dans une chambre de rinçage (80), qui est située au-dessus de l'élément d'excavation
(71), où elle est mélangée avec un liquide de rinçage, qui est introduit dans la chambre
de rinçage (80) sous pression, via au moins une conduite d'alimentation (81), avant
d'être déchargée vers le haut à l'extérieur de l'élément de fondation (50), conjointement
au liquide de rinçage, via au moins une conduite de décharge (82).
2. Procédé selon la revendication 1, dans lequel la pression du liquide de rinçage alimenté
est déterminée selon une valeur qui est supérieure à la pression sous-marine prédominant
dans le sol environnant, en particulier une pression excessive d'approximativement
0,1-0,3 bar.
3. Procédé selon la revendication 1 ou 2, dans lequel une plaque de base (78) qui est
prévue avec des ouvertures d'introduction (79) et délimite la face inférieure de la
chambre de rinçage (80), est déplacée sensiblement vers le haut et vers le bas dans
la direction de l'élément d'excavation (71) dans le cas dans lequel un problème est
détecté.
4. Procédé selon l'une quelconque des revendications précédentes, dans lequel, si l'élément
de fondation (50), alors qu'il est enfoncé, commence à dévier de la direction d'introduction
prévue, la position au moins de l'arbre d'entraînement (70) conjointement à l'élément
d'excavation (71) de la tête de forage (55), est ajustée par rapport à l'élément de
fondation (50).
5. Procédé selon l'une quelconque des revendications précédentes, dans lequel, pendant
l'enfoncement de l'élément de fondation (1), une force de compression dirigée vers
le bas est exercée sur l'élément de fondation (1), à l'aide d'une installation de
pression (2) qui est supportée sur le sol au moyen d'un châssis et est en particulier
ancrée au sol.
6. Procédé selon l'une quelconque des revendications précédentes, dans lequel la tête
de forage (55), alors que l'élément de fondation (50) est enfoncé, est positionnée
par rapport à l'élément de fondation (50) de sorte que la tête de forage (55) est
positionnée partiellement à l'intérieur de l'élément de fondation (50), alors que
la partie résiduelle est positionnée au-dessous de la partie inférieure de l'élément
de fondation (50).
7. Procédé selon la revendication 6, dans lequel la tête de forage (55), pendant le forage,
est fixée à une partie de paroi périphérique interne (52) de la partie inférieure
de l'élément de fondation (50) à l'aide d'un élément de serrage contrôlable (60).
8. Procédé selon l'une quelconque des revendications précédentes, dans lequel l'élément
d'excavation (10) peut être déplacé par rapport à l'arbre d'entraînement, sensiblement
dans un plan qui est perpendiculaire à la direction d'introduction, et après que l'élément
de fondation (10) a été enfoncé, l'élément d'excavation (10) est déplacé de la position
de forage dans une position au repos, dans laquelle l'élément d'excavation (10) a
des dimensions radiales qui sont plus petites que les dimensions internes de l'élément
de fondation (14), après quoi la tête de forage (9) est rétractée vers le haut à travers
l'intérieur de l'élément de fondation (14).
9. Procédé selon l'une quelconque des revendications précédentes, dans lequel, avant
que la tête de forage (3) ne soit rétractée vers le haut, l'élément de fondation (1)
est rempli avec du liquide.
10. Procédé selon l'une quelconque des revendications précédentes, dans lequel, après
que la tête de forage (9) a été rétractée, l'élément de fondation (14) est au moins
partiellement rempli avec un matériau de fondation (26).
11. Procédé selon l'une quelconque des revendications précédentes, dans lequel, après
que l'élément de fondation (30) a été enfoncé, la tête de forage et/ou l'élément de
fondation (30) sont remontés, avec l'injection simultanée d'un matériau de fondation
(31), en particulier un matériau de fondation durcissable.
12. Procédé selon l'une quelconque des revendications précédentes, dans lequel, pendant
l'opération de l'enfoncement, une ou plusieurs conduites d'injection sont entraînées
afin d'alimenter le matériau de fondation après que l'élément de fondation a été enfoncé.
13. Procédé selon l'une quelconque des revendications précédentes, dans lequel, pendant
l'opération de l'enfoncement, une ou plusieurs conduites d'injection sont entraînées
afin d'alimenter du lubrifiant autour de l'élément de fondation alors qu'il est introduit
dans le sol.
14. Procédé selon l'une quelconque des revendications précédentes, dans lequel, chaque
élément de fondation (1) est composé de segments, en particulier avec une hauteur
inférieure à 2 mètres, qui peuvent être assemblés les uns aux autres, en particulier
par soudage.
15. Procédé selon l'une quelconque des revendications précédentes, dans lequel, l'élément
de fondation, dans la section au-dessus de la tête de forage, alors qu'il est enfoncé,
est rempli avec du liquide, en particulier de l'eau.
16. Système destiné à être utilisé en particulier avec le procédé selon l'une quelconque
des revendications 1 à 15, comprenant :
au moins un élément de fondation creux (50) ;
une installation (2) conçue pour exercer une force orientée sensiblement verticalement
sur l'élément de fondation (50) ; et
une tête de forage (55) qui peut être descendue dans l'élément de fondation et a au
moins un élément d'excavation qui peut tourner autour d'un arbre d'entraînement et,
dans une position de forage, alors que l'élément de fondation (50) est enfoncé dans
le sol, a des dimensions radiales qui sont en particulier supérieures ou égales aux
dimensions externes de l'élément de fondation (50), caractérisé en ce que :
la tête de forage (55) comprend une chambre de rinçage (80), qui est positionnée au-dessus
de l'élément d'excavation (71) et sur la surface inférieure, comprend des ouvertures
d'introduction (79) prévues en particulier dans une plaque de base (78), à laquelle
chambre de rinçage (80), au moins une conduite d'alimentation (81) pour introduire
un liquide de rinçage dans la chambre de rinçage (80) sous pression est raccordée,
et à laquelle chambre de rinçage, au moins une conduite de décharge (82) pour décharger
le liquide de rinçage mélangé à la terre qui a été forée hors de la chambre de rinçage
(80).
17. Système selon la revendication 16, dans lequel les ouvertures d'introduction (79)
s'élargissent dans la direction ascendante.
18. Système selon la revendication 16 ou 17, dans lequel des éléments de déplacement (84)
sont prévus dans la tête de forage (55) pour déplacer la plaque de base (78) sensiblement
vers le haut et vers le bas dans la direction de l'élément d'excavation (71).
19. Système selon la revendication 18, dans lequel les éléments de déplacement (84) comprennent
des cylindres de déplacement hydrauliques.
20. Système selon la revendication 18 ou 19, dans lequel les éléments de déplacement (84)
agissent entre la plaque de base (78) et une partie de logement (62) de la tête de
forage (55) qui, pendant le forage, peuvent être fixées en position par rapport à
l'élément de fondation (50).
21. Système selon l'une quelconque des revendications 16 à 20, dans lequel des éléments
de commande (74) sont prévus dans la tête de forage (55) pour ajuster la position
de l'arbre d'entraînement (70) avec l'élément d'excavation (71) par rapport à une
partie inférieure de l'élément de fondation (50).
22. Système selon la revendication 21, dans lequel les éléments de commande (74) comprennent
des cylindres de commande hydrauliques.
23. Système selon la revendication 21 ou 22, dans lequel les éléments de commande (74)
sont actifs entre un rebord de montage (64) dans lequel l'arbre d'entraînement (70)
est monté et une partie de logement (62) de la tête de forage (55) qui, pendant le
forage, peut être fixée en position par rapport à la partie inférieure de l'élément
de fondation (55).
24. Système selon l'une quelconque des revendications 21 à 23, dans lequel les éléments
de commande (74) agissent pour ajuster la position de l'arbre d'entraînement (70)
conjointement à l'élément d'excavation (71) par rapport à la partie inférieure de
l'élément de fondation (55) dans une direction qui est sensiblement perpendiculaire
à l'arbre d'entraînement (70).
25. Système selon l'une quelconque des revendications 21 à 23, dans lequel les éléments
de commande (74) agissent pour incliner la position angulaire de l'arbre d'entraînement
conjointement à l'élément d'excavation (71) par rapport à la partie inférieure de
l'élément de fondation (50).
26. Système selon l'une quelconque des revendications 16 à 25, dans lequel la partie inférieure
de l'élément de fondation (55) est prévue avec une partie de paroi périphérique (53)
se rétrécissant progressivement vers le bas.
27. Système selon l'une quelconque des revendications 16 à 26, dans lequel on trouve des
moyens de mesure pour déterminer la direction d'introduction de l'élément de fondation,
lesquels moyens de mesure interagissent avec et/ou sont prévus sur la tête de forage.
28. Système selon l'une quelconque des revendications 16 à 27, dans lequel la tête de
forage (55) comprend une unité d'entraînement (65) pour entraîner l'arbre d'entraînement
(70), en particulier un moteur hydraulique.
29. Système selon la revendication 28, dans lequel des mécanismes d'engrenage planétaires
sont prévus en tant que transmission entre l'unité d'entraînement (65) et l'arbre
d'entraînement (70).
30. Système selon l'une quelconque des revendications 16 à 29, dans lequel l'installation
est une installation de presse (20) qui comprend un châssis qui peut être supporté
sur le sol, en particulier peut être ancré au sol, et qui est prévu avec des moyens
de mise en prise, qui peuvent monter et descendre grâce aux moyens hydrauliques par
rapport au châssis, pour exercer une force de compression dirigée vers le bas sur
l'élément de fondation (50).
31. Système selon la revendication 30, dans lequel les moyens de mise en prise peuvent
également être ajustés de manière contrôlable par rapport au châssis dans une direction
qui est sensiblement perpendiculaire à la direction de pression descendante.
32. Système selon l'une quelconque des revendications 16 à 31, dans lequel la tête de
forage (55) comprend des moyens de serrage contrôlables (60) pour la serrer en toute
sécurité sur une partie de paroi périphérique interne (52) d'une partie inférieure
de l'élément de fondation (50).
33. Système selon l'une quelconque des revendications 16 à 32, dans lequel on prévoit
une partie inférieure de l'élément de fondation (50) le long de sa paroi périphérique
interne, avec un bord de butée (56) pour délimiter la tête de forage (55) vers le
bas.
34. Système selon l'une quelconque des revendications 16 à 33, dans lequel une partie
inférieure de l'élément de fondation (50) est prévue, le long de sa paroi périphérique
interne, avec des pattes de positionnement (51) pour positionner la tête de forage
(55).
35. Système selon l'une quelconque des revendications 16 à 34, dans lequel l'élément d'excavation
(71) peut être déplacé par rapport à l'arbre d'entraînement sensiblement dans un plan
qui est perpendiculaire à l'arbre d'entraînement, entre la position de forage et une
position au repos dans laquelle l'élément d'excavation (71) a des dimensions radiales
qui sont plus petites que les dimensions internes de l'élément de fondation (50).
36. Système selon l'une quelconque des revendications 16 à 35, dans lequel on trouve une
ou plusieurs conduits d'injection pour alimenter le matériau de fondation après que
l'élément de fondation a été enfoncé.
37. Système selon l'une quelconque des revendications 16 à 36, dans lequel on trouve une
ou plusieurs conduites d'injection pour alimenter le lubrifiant autour de l'élément
de fondation alors qu'il est introduit dans le sol.
38. Système selon la revendication 37, dans lequel la conduite d'injection s'ouvre derrière
un chevauchement dans la paroi périphérique d'une partie inférieure de l'élément de
fondation.
39. Système selon l'une quelconque des revendications 16 à 38, dans lequel chaque élément
de fondation (50) comprend des segments, en particulier avec une hauteur inférieure
à 2 mètres, et dans lequel on trouve des moyens pour raccorder les segments entre
eux.
40. Système selon la revendication 39, dans lequel la tête de forage (55) a une hauteur
totale qui est inférieure à la hauteur d'un segment de l'élément de fondation (50).
41. Système selon l'une quelconque des revendications 16 à 40, dans lequel la tête de
forage (55) a une hauteur totale qui est inférieure à 2 mètres.
REFERENCES CITED IN THE DESCRIPTION
This list of references cited by the applicant is for the reader's convenience only.
It does not form part of the European patent document. Even though great care has
been taken in compiling the references, errors or omissions cannot be excluded and
the EPO disclaims all liability in this regard.
Patent documents cited in the description