U.S. patent application number 14/176160 was filed with the patent office on 2015-08-13 for foundation with slab, pedestal and ribs for columns and towers.
The applicant listed for this patent is Ahmed Phuly. Invention is credited to Ahmed Phuly.
Application Number | 20150225918 14/176160 |
Document ID | / |
Family ID | 53718847 |
Filed Date | 2015-08-13 |
United States Patent
Application |
20150225918 |
Kind Code |
A1 |
Phuly; Ahmed |
August 13, 2015 |
FOUNDATION WITH SLAB, PEDESTAL AND RIBS FOR COLUMNS AND TOWERS
Abstract
A fatigue resistant gravity based spread footing under heavy
multi-axial cyclical loading of a wind tower. The foundation having
a central vertical pedestal, a substantially horizontal continuous
bottom support slab with a stiffened perimeter, a plurality of
radial reinforcing ribs extending radially outward from the
pedestal. The pedestal, ribs and slab forming a continuous
monolithic structure. The foundation having a three-dimensional
network of post-tensioning elements that keep the structural
elements under heavy multi-axial post compression with a specific
eccentricity intended to reduce stress amplitudes and deflections
and allows the foundation to have a desirable combination of high
stiffness and superior fatigue resistance. The foundation design
reduces the weight and volume of materials used, reduces cost, and
improves heat dissipation conditions during construction by having
a small ratio of concrete mass to surface area thus eliminating the
risk of thermal cracking due to heat of hydration.
Inventors: |
Phuly; Ahmed; (Andover,
MN) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Phuly; Ahmed |
Andover |
MN |
US |
|
|
Family ID: |
53718847 |
Appl. No.: |
14/176160 |
Filed: |
February 10, 2014 |
Current U.S.
Class: |
52/297 |
Current CPC
Class: |
Y02B 10/30 20130101;
Y02P 70/50 20151101; F05B 2230/50 20130101; E02B 2017/0091
20130101; Y02E 10/72 20130101; E04G 21/12 20130101; E02B 17/025
20130101; E02D 27/08 20130101; E02D 27/42 20130101; E04G 21/02
20130101; B28B 1/14 20130101; F05B 2240/912 20130101; E02B
2017/0073 20130101; E02B 2017/0069 20130101; E02B 2017/006
20130101; E02D 27/26 20130101; E02D 27/425 20130101; E04H 12/08
20130101; E02D 27/02 20130101; E04H 12/341 20130101; E02B 17/027
20130101; Y02E 10/728 20130101; E04H 12/16 20130101; F03D 13/22
20160501 |
International
Class: |
E02D 27/42 20060101
E02D027/42; E04H 12/16 20060101 E04H012/16; E02D 27/08 20060101
E02D027/08 |
Claims
1. A foundation comprising, a concrete support slab having
horizontal rebar therein, a concrete pedestal integral with the
support slab having vertical rebar therein, a plurality of concrete
ribs on top of and integral with the support slab and integral with
the pedestal, the ribs having connection elements extending from
the ribs into the pedestal and from the ribs into the slab, a
perimeter beam in the slab.
2. A foundation as in claim 1 wherein, the foundation includes a
post tensioning element in the perimeter beam.
3. A foundation as in claim 1 wherein, the foundation includes a
post tensioning element in the ribs.
4. A foundation as in claim 1 wherein, the foundation includes a
post tensioning element in the slab.
5. A foundation as in claim 1 wherein, the pedestal having an
embedment ring near the base of the pedestal and a tower base at
the top of the pedestal with vertical anchor bolts extending
between the embedment ring, and tower base for vertical post
tensioning of the foundation.
6. A foundation as in claim 5 wherein, the anchor bolts are bond
protected.
7. A foundation comprising, a concrete support slab having
horizontal rebar therein, a concrete pedestal integral with the
support slab having vertical rebar therein, a vertical concrete
stem attached to the pedestal, a plurality of concrete ribs on top
of and integral with the support slab and integral with the
pedestal, the ribs having connection elements extending from the
ribs into the pedestal and from the ribs into the slab, a perimeter
beam in the slab.
8. A foundation as in claim 7 wherein, a plurality of post
tensioning elements extend through the pedestal and the stem for
prestressing the pedestal and stem.
9. A foundation as in claim 7 wherein, the foundation has an array
of anchor bolts at the top of the stem for receiving and supporting
a tower base.
10. A foundation as in claim 7 wherein, the foundation includes a
post tensioning element in the perimeter beam.
11. A foundation as in claim 7 wherein, the foundation includes a
post tensioning element in the ribs.
12. A foundation as in claim 7 wherein, the foundation includes a
post tensioning element in the slab.
13. A foundation as in claim 11 wherein, the foundation includes a
post tensioning element in the perimeter beam.
14. A foundation as in claim 11 wherein, the foundation includes a
post tensioning element in the slab.
15. A foundation as in claim 14 wherein, the foundation includes a
post tensioning element in the perimeter beam.
16. (canceled)
17. (canceled)
Description
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of Ser. No. 13/319,083
filed Nov. 5, 2011 which claims the benefit of provisional
applications 61/215,430 filed May 5, 2009, 61/269,800 filed Jun.
29, 2009, 61/284,901 filed Dec. 28, 2009, 61/339,550 filed Mar. 5,
2010 and claims priority from PCT/US/2010/041006 and is a
continuation-in-part of patent application Ser. No. 12/774,727
filed May 6, 2010, which is a continuation-in-part of patent
application Ser. No. 11/859,588 filed Sep. 21, 2007 which claims
the benefit of applications provisional applications 60/826,452
filed Sep. 21, 2006 and 60/954,502 filed Aug. 7, 2007.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] This invention relates to building fatigue resistant
foundations for supporting columns, towers and structures under
heavy cyclical loads such as for onshore and offshore wind turbine
towers. Wind turbine support structures are subjected to high
cyclical loading with the number of load cycles up to 10.sup.9.
Therefore, the fatigue design becomes more important for concrete
construction and the influence of multi-stage and multi-axial
fatigue loading have to be considered. Studies have recommended
modification of the design rules for concrete construction of wind
turbine foundations in order to consider the influence of
multi-axial loading.
[0004] Wind turbine manufacturers have successfully developed large
wind turbines with rated power ranging from 1.5 to 10 MW, for
onshore and offshore installations. The E-126 model turbine by
Enercon with a 7 MW rated power required a 29 meter diameter
circular foundation with 1,400 cubic meters of concrete and 120
tons of rebar. The RePower 5M turbine with a 5 MW rated power
required a 23 meter diameter circular foundation with 1,300 cubic
meters of concrete and 180 tons of rebar. The task of building such
large foundations is monumental and requires a great deal of
construction planning and logistics. The proposed foundation
designs and their associated construction methods provide
cost-effective solutions for such challenging foundation
projects.
[0005] Some wind turbine installations that have been constructed
in the last 10 years in the US and Europe have encountered
structural problems stemming from thermal cracking during
construction, or from fatigue cracking requiring repairs. The
present invention improves the geometry of the foundation in order
to enhance dissipation conditions for the typical temperature rise
due to heat of hydration after casting and also provides a cost
effective fatigue resistant design.
[0006] 2. Description of the Related Art
[0007] Conventional gravity style foundations for large wind
turbines usually comprise a large, thick, horizontal, heavily
reinforced cast in situ concrete base; and a vertical cast in situ
cylindrical pedestal installed over the base. There are several
problems typically encountered during the construction of such
foundations.
[0008] Fatigue resistance of such conventional footings is achieved
by over sizing the structural concrete elements and the reinforcing
elements such that the resulting stress amplitudes are small enough
for the structural elements to pass fatigue design checks.
[0009] The main problem is the monumental task of managing large
continuous concrete pours, which require sophisticated planning and
coordination in order to pour large amounts of concrete per
footing, in one continuous pour, without having any cold joints
within the pour.
[0010] Another problem is logistics coordinating with multiple
local batch plants the delivery plan of the large number of
concrete trucks to the job site in a timely and organized
manner.
[0011] A further problem is the complexity of installing the rebar
assembly into the foundation which requires assembling two layers
of steel reinforcing meshes that are two to six feet apart across
the full area of the foundation, while maintaining a strict
geometric layout and specific spacing. This rebar assembly is made
of extremely long and heavy rebar which requires the use of a crane
in addition to multiple workers to install all the components of
the assembly. The rebar often exceeds forty feet in length, thus
requiring special oversized shipments which are very expensive and
usually require special permits. The installation of the rebar is a
labor intensive and time consuming task requiring a large number of
well trained rebar placing workers.
[0012] Another important problem is the fact that the majority of
the construction process consists of field work which can easily be
compromised by weather conditions and other site conditions.
[0013] Another problem is thermal cracking of concrete due to
overheating of the concrete mass. When concrete is cast in massive
sections, the temperature can reach high levels and the risk of
thermal cracking becomes very high. Thermal cracking often
compromises the structural integrity of foundations as reported in
many projects in Europe and North America.
[0014] Multi-cell caissons used in offshore installations always
lack multi-axial post-tensioning elements and their fatigue
resistance relies completely on heavily reinforced oversized
concrete elements which involves expensive and labor intensive
construction.
BRIEF SUMMARY OF THE INVENTION
[0015] It is desired to have a cost-effective foundation which
reduces the amount of construction material used in the
construction of wind turbines. This can be accomplished by the use
of concrete rib stiffeners, with a cast in place slab on grade
element and a central pedestal to build an integral foundation that
will behave structurally as a monolithic foundation structure.
Other concrete components can be included such as secondary and
perimeter beams, diaphragms, or intermediate stiffeners and rib
stiffened or flat slab sections. The foundation system may use
prefabricated components including rebar meshes and cages, a
pedestal cage assembly, precut post-tensioning strands,
preassembled strand bundles, precut post-tensioning duct sections
and prefabricated concrete forms.
[0016] The present invention pertains to a fatigue resistant
foundation for wind towers which comprises a plurality of
components, namely a central vertical pedestal, a substantially
horizontal continuous bottom support slab with a stiffened
perimeter, a plurality of radial reinforcing ribs extending
radially outwardly from the pedestal and a three-dimensional
network of vertical, horizontal, diagonal, radial and
circumferential post-tensioning elements embedded in the footing
that keeps all the structural elements under heavy multi-axial post
compression, which reduces stress amplitudes and deflections and
allows the foundation to have a desirable combination of high
stiffness and superior fatigue resistance while improving heat
dissipation conditions during construction by having a small ratio
of concrete mass to surface area thus eliminating the risk of
thermal cracking due to heat of hydration.
[0017] Although the application is written with a wind turbine
tower as the column being supported by the foundation, any tower or
column can be used on the foundation including but not limited to,
antennas, chimneys, stacks, distillation columns, water towers,
electric power lines, bridges, buildings, or any other structure
using a column.
[0018] In one embodiment of the invention a wind turbine foundation
has a plurality of components, namely a central vertical pedestal,
a substantially horizontal bottom support slab, and a plurality of
radial reinforcing ribs extending radially outwardly from the
pedestal, the ribs are prefabricated and transported to job site,
but the pedestal and support slab are poured in situ at the site
out of concrete. The prefabricated ribs 16 are equipped with load
transfer mechanisms, for shear force and bending moment, along the
conjunctions with the cast in situ support slab, pedestal and
perimeter beams. The prefabricated ribs are also equipped at their
inner ends with load transfer mechanisms, for shear force and
bending moment, along the conjunctions with the cast in situ
pedestal. The ribs are arranged in a circumferentially spaced
manner around the outer diameter of the pedestal cage assembly
before or after slab reinforcing steel is installed. Forms are then
arranged for the pedestal and support slab. The support slab is
cast in situ by pouring concrete into the forms and then pedestal
concrete is poured into the pedestal form over the slab. When the
concrete cures the support slab 20 is united to the prefabricated
ribs 16 and the ribs 16 are also united to the pedestal 10. The
final result is a continuous monolithic polygon or circular shaped
foundation wherein loads are carried across the structure
vertically and laterally through a continuous structure by the
doweled and spliced reinforcing steel bars which are integrally
cast into the pedestal 10, ribs 16 and support slab 20. The
combination of the high stiffness of the ribs 16, solid pedestal 10
and continuous slab 20 construction across the pedestal 10, and
through or under ribs 16, allows the slab 20 to behave structurally
as a continuous slab over multiple rigid supports resulting in
small bending and shear stresses in the slab 20, reducing
deflections and increasing the stiffness of the foundation 100,
improving fatigue conditions as well as allowing for the benefits
of an economical design. Support slab reinforcing steel covers the
entire footprint of the foundation and extends, without
interruption, across the slab area and into the pedestal 10 to
improve the structural performance of the foundation 100 under
different loading conditions. Perimeter beams 190 or thickened slab
edges 21 around the perimeter add stiffness and strength to the
foundation 100 and provide the benefits of a two-way slab system.
Circumferential post-tensioning of the slab edge 21 is used to
increase the structural capacity of the ribs 16 and the pedestal 10
by creating eccentric post-compression force in the ribs 16 and by
reducing stress amplitudes in the slab 20, ribs 16 and pedestal
10.
[0019] The foundation of the present invention substantially
reduces the amount of concrete used in a wind turbine foundations
of spread footing style, simplifies the placement of rebar and
concrete in the foundation, allows for labor and time savings and
shortens the foundation construction schedule when compared to
conventional foundation designs.
[0020] This invention provides the wind energy industry with a
foundation system suitable for utility scale wind turbines
including 1.5 MW through 10 MW or larger turbines, wherein the
amount of cast in situ concrete work is limited, and the number of
concrete trucks required for the foundation is kept to a smaller
and more manageable level, and the amount of rebar used in the
foundation is around 60% less than conventional footings.
[0021] The present invention uses prefabricated components that
meet size and weight limits for standard ground freight shipping on
typical roads and highways, without resorting to special permitting
for oversize or overweight shipments, keeping in mind that the
foundation width for large turbines can easily exceed sixty
feet.
[0022] One embodiment of the invention uses specific combinations
of precast components with cast in situ components designed to
speed up construction without compromising the rigidity and
structural continuity and optimization of the foundation. The
combination of high strength, high stiffness prefabricated ribs,
solid pedestal construction and continuous slab construction across
the pedestal, and through or under the ribs, allows the slab to
behave structurally as a continuous slab under multiple rigid
supports resulting in small bending and shear stresses in the slab,
reducing deflections and increasing the stiffness of the
foundation, substantially reducing fatigue as well as allowing for
the benefits of rapid construction and economical design.
[0023] The present invention improves the geometry of the
foundation in order to enhance dissipation conditions for the heat
of hydration due to the typical temperature rise after casting.
This design feature is achieved by reducing the thickness of the
support slab and the ratio of concrete mass to surface area, thus
reducing the risk of thermal cracking and protecting the structural
integrity of the foundations.
[0024] The present invention optimizes the design support slab by
configuring slab reinforcing to span between supporting ribs, and
allowing it to continue under or across the ribs. Each slab panel
may be triangular or pie-shaped and is prestressed along all three
sides such that a multi-axial prestress is generated in each slab
panel. Slab panels with radial and perimeter post tensioning
elements form a robust horizontal trussed diaphragm and as a
result, the required slab thickness is optimized and the amount of
cast in situ concrete is reduced.
[0025] The present invention reduces the maximum rebar length for
field installation to approximately half the conventional length,
to roughly 7.6 meters (twenty five feet), which is significantly
shorter when compared to conventional footing that may requires
15.2 to 18.3 meters (fifty to sixty foot) long reinforcing
bars.
[0026] The present invention allows rib dowels, or post tensioning
tendons, extending inwardly into the pedestal at one end, to
continue without interruption between distal ends of the
foundation. As a result each pair of ribs 16 on opposite ends of
the pedestal 10 will behave structurally as one continuous beam
across the width of the foundation 100.
[0027] The present invention reduces fatigue for concrete and rebar
in the foundation by minimizing stress concentrations through
appropriately configured connections and component geometry. The
solid and deep construction of the pedestal allows for great
reduction of stresses across the pedestal and at the conjunctions
between the pedestal and the surrounding slab and ribs. Dowels from
the ribs into the pedestal are relatively deep to reduce stresses
in the surface zone of the pedestal and can be paired with
corresponding dowels extending from the opposite end of the
foundation. The solid pedestal offers desirable bearing conditions
for the tower base plate and improves the geometry as needed to
minimize fatigue.
[0028] The present invention employs prestressing and/or post
tensioning techniques in order to maximize the performance of the
foundation, and to extend its life span. Besides the vertical
tensioning of anchor bolts, tensioning of horizontal and diagonal
tendons are employed along the length of the concrete ribs and
across the pedestal. Further, perimeter and radial post tensioning
elements embedded in the slab are employed. Post-tensioning of the
ribs is designed in an eccentric manner to counter balance and
reduce the stresses from the dead loads on the foundation. This can
be accomplished by setting an eccentric post tensioning load
pattern in the ribs with higher axial force at the bottom than at
the top of the rib. The circumferential post tensioning load in the
slab provides additional desirable eccentric prestressing of the
ribs and the pedestal and helps increase rib load capacity and rib
fatigue resistance.
OBJECTS OF THE INVENTION
[0029] An object of this invention is to provide the wind energy
industry with a short construction time, reliable, and cost
effective foundation system suitable for most wind energy projects,
including projects using the largest utility scale turbines and
tallest towers, while providing a foundation lifespan that is
longer than conventional foundation systems.
[0030] Another object of this invention is to reduce the cost of
wind energy projects by realizing savings in the areas of reducing
concrete and rebar quantity, reducing concrete trucking service,
decreasing concrete pouring and finishing, improving logistics, and
reducing man-hours and crane operations.
[0031] It is the object of this invention to provide a foundation
suitable for large wind turbines including utility scale turbines
ranging from 1.5 MW to 10 MW and larger, wherein the amount of cast
in situ concrete work is limited and the number of concrete trucks
and the amount of rebar required for the foundation is reduced to a
manageable level when compared to conventional gravity style
foundations.
[0032] Another object of this invention is to improve dissipation
conditions for the heat of hydration and the typical temperature
rise after casting. This goal is achieved by reducing the ratio of
concrete mass to surface area. When concrete is cast in massive
sections for wind tower foundations, temperatures can reach high
levels and the risk of thermal cracking becomes very high unless
cooling techniques or special admixtures are applied. Thermal
cracking often compromises the structural integrity of the
foundations.
[0033] A further object of one embodiment of this invention is to
improve foundation structural properties due to fabrication of some
structural components in a fully controlled environment of a
precast concrete plant or a suitable facility at or near the
project site and to utilize and benefit from advancement in
concrete construction in areas such as concrete admixtures, special
cements and fiber reinforcement.
[0034] Still another object of this invention is to utilize
desirable features and benefits associated with mass production of
precast concrete such as high reliability and uniform consistency
and high compressive strength.
[0035] Another important object of this invention is to minimize
chances for errors in bar placement, spacing and layout by
providing pre-marked spacing for splicing slab rebar with existing
dowels extending from ribs.
[0036] A further object of this invention is to use light weight,
small diameter, short and easy to handle rebar for the cast in situ
concrete.
[0037] A further object of this invention is to provide the wind
energy industry with a solution for all weather foundation
construction.
[0038] Still another object of this invention is to improve safety
and accessibility around foundations under construction, and reduce
hazardous conditions for construction crews.
[0039] A further object of this invention is to increase
productivity and increase the number of footings that can be built
in a given time frame using the same number of workers, when
compared to conventional foundation designs built under similar
conditions.
[0040] Another object of this invention is to employ prestressing
and/or post tensioning techniques in order to maximize the
performance of the foundation, improve its fatigue resistance and
extend its life span.
[0041] Another object of this invention is to provide the wind
energy industry with reliable and readily available designs, and
optionally, prefabricated components, for every wind energy
project, wherein foundation designs are pre-approved by and
coordinated with turbine manufactures and certification
agencies.
[0042] A further object of this invention is to use standard
designs to reduce engineering work and simplify the permitting
process, as well as improve the project construction schedule.
[0043] Still another object of this invention is to speed-up
construction by using many prefabricated components including rebar
meshes and cages, bolt cage assemblies, pre-cut post-tensioning
strands, preassembled post-tensioning bundles, pre-cut
post-tensioning duct sections and prefabricated concrete forms and
optionally, precast ribs.
[0044] It is also the object of this invention is to provide wind
energy developers with the ability to select pre-approved complete
foundation designs for wind turbine foundations based on project
and site variables including turbine model and tower height; site
geotechnical characteristics; and desired foundation styles such as
gravity, anchored or piling support foundations.
[0045] Another object of this invention is to provide foundation
contractors with the convenience and economy of using commercially
available prefabricated components with complete assembly and
detail drawings that can be delivered to any project site with
short lead times.
[0046] A further object of this invention is to improve the quality
and productivity of foundation construction due to experience
gained from practicing standard construction techniques with
repetitive production steps.
[0047] Still another object of his invention is to produce
foundation designs suitable for shallow and deep offshore
installations.
[0048] Another object of this invention is to use the modular
foundation system for other tower structures such as chimneys,
stacks, distillation columns, telecommunication towers, and water
towers.
[0049] Yet another object of the invention is to improve tower base
bearing resistance in concrete pedestals supporting wind towers
such that it becomes possible to build the pedestal and the
foundation with concrete having the same compressive strength
without increasing the diameter of the pedestal.
[0050] Another object of the invention is to build wind tower
foundations in one continuous concrete pour.
[0051] Another object of the invention is to independently produce
prefabricated components for offshore foundations to be assembled
on a barge without having the critical path of completing a first
component before a second component can be constructed.
[0052] Other objects, advantages and novel features of the present
invention will become apparent from the following description of
the preferred embodiments when considered in conjunction with the
accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0053] FIG. 1 is a plan view of the foundation.
[0054] FIG. 2 is a sectional elevation view of the foundation cut
near the ribs.
[0055] FIG. 3 is sectional elevation view of the foundation.
[0056] FIG. 4 is a section detail of a cast-in-situ slab and
pedestal showing the different reinforcing groups in both
elements
[0057] FIG. 5 is a partial sectional elevation of the foundation
showing different bar reinforcing groups of a rib along with dowels
for connecting to a pedestal and a slab.
[0058] FIG. 6 is a partial plan view of the foundation showing
different bar reinforcing groups of a rib along with dowels for
connecting to a pedestal and a slab.
[0059] FIG. 7 is a partial sectional elevation of the foundation
showing different post-tension reinforcing groups of a rib along
with post-tension dowels for connecting to a pedestal and a
slab.
[0060] FIG. 8 is a partial plan view of the foundation showing
different post-tension reinforcing groups of a rib along with
dowels for connecting to a pedestal and a slab.
[0061] FIG. 9 is a slab reinforcing plan view showing the different
reinforcing groups of a lower slab reinforcing assembly along with
perimeter reinforcing cages.
[0062] FIG. 10 is a slab reinforcing plan view showing the
different reinforcing groups of an upper slab reinforcing assembly
along with perimeter reinforcing cages.
[0063] FIG. 11 is a vertical section view of a pedestal showing the
different bar reinforcing groups of a pedestal including the two
confinement cages surrounding the anchor bolt assembly. Rib and
slab dowels are not shown for clarity.
[0064] FIG. 12 is a partial vertical section view of the foundation
showing different bar reinforcing groups of a pedestal including
the two confinement cages surrounding the anchor bolt assembly. Rib
and slab dowels are not shown for clarity.
[0065] FIG. 13 is a plan view of a foundation with a heavily post
tensioned ring beam using ring anchors and 180-degree ring
tendons.
[0066] FIG. 14 is a plan view of a partially prefabricated
foundation with a heavily post tensioned ring beam extending above
the slab and using ring anchors and 180-degree ring tendons with
anchor blisters extending from the foundation. General arrangement
of temporary rib support and drains is shown.
[0067] FIG. 15 is a sectional elevation view of a partially
prefabricated foundation with a heavily post tensioned ring beam
extending above the slab and using ring anchors and 180-degree ring
tendons with anchor blisters extending from the foundation. General
arrangement of temporary rib support and their corresponding
sub-footings is shown.
[0068] FIG. 16 is a plan view of a partially prefabricated
foundation with a heavily post tensioned ring beam extending above
the slab and using ring anchors and 180-degree ring tendons with
anchor blisters extending from the foundation. General arrangement
of temporary rib support and drains is shown.
[0069] FIG. 17 is a partial plan view of a partially prefabricated
foundation showing a general arrangement of lower radial post
tensioning ducts in the rib inner zones and across the
pedestal.
[0070] FIG. 18 is a partial plan view of a partially prefabricated
foundation showing a general arrangement of upper radial post
tensioning ducts in the rib inner zones and across the
pedestal.
[0071] FIG. 19 is a partial plan view showing a general arrangement
of radial post tensioning duct spacing in the pedestal.
[0072] FIG. 20 is a partial section view of a partially
prefabricated foundation showing a general arrangement of upper and
lower radial post tensioning ducts in the rib inner zones and
across the pedestal.
[0073] FIG. 21 is an elevation view of a prefabricated rib showing
post-tensioning ducts and an anchor arrangement. Rib bottom dowels
for slab connection and concrete shear key corrugations are
shown.
[0074] FIG. 22 is a plan view of a prefabricated rib showing
post-tensioning ducts and an anchor arrangement. Rib side dowels
for the ring beam connection and concrete shear key corrugations
are shown.
[0075] FIG. 23 is a plan view of a foundation having a hexagonal
footprint and a thickened and heavily post tensioned slab edge. A
simplified force diagram shows the cumulative resultant (R) of
radial post tension (PT1) and perimeter post tension (PT2). The
resultant is the effective post-tension force acting at rib end is
defined by the equation: R=PT1+2 PT2 (cos a), where (a) is the
angle between PT1 and PT2. In this configuration all ribs are
subjected to equal heavy eccentric post compression stresses that
maximize rib structural resistant to governing tower loads.
[0076] FIG. 24 is the effective rib cross section showing the
neutral axis 16n and the eccentricity (eR) of the effective post
tensioning force R.
[0077] FIG. 25a is a diagram that shows a foundation cross section
post tensioning, before a tower dead load and backfilling are
added.
[0078] FIG. 25b is a diagram that shows cambers in the foundation
of FIG. 25a.
[0079] FIG. 25c is a diagram that shows a foundation cross section
post tensioning, after a tower dead load and backfilling are
added.
[0080] FIG. 25d is a diagram that shows cambers in the foundation
of FIG. 25c, after tower dead load and backfilling are added.
[0081] FIG. 26 is a section view of a foundation having an embedded
tower section in the pedestal.
[0082] FIG. 27 is a connection detail showing an alternative
doweling method between a prefabricated rib and a slab where dowels
extend down from the rib into grouted sleeves arranged in a
slab.
[0083] FIG. 28 is a connection detail showing an alternative
doweling method between a cast-in-situ rib and a slab where dowels
extend up from the slab into rib forms to mesh with rib reinforcing
elements.
[0084] FIG. 29 is a connection detail showing an un-bonded rock
anchor connection to the foundation with bearing and tensioning
elements receiving an anchor bolt extending through vertical holes
in the foundation.
[0085] FIG. 30 is a connection detail showing a bonded rock anchor
connection to the foundation with bearing and tensioning elements
receiving an anchor bolt extending through vertical holes in the
foundation. The anchor is tensioned and grouted to a specific
depth. The anchor may be configured to function as a pile
anchor.
[0086] FIG. 31 is a section of a foundation comprising a concrete
stem extending above the pedestal and the post tension duct with
loop anchors are a arranged to facilitate the vertical post
tensioning of the stem and the pedestal.
[0087] FIG. 32 is a detail that shows perimeter and radial post
tensioning in a foundation with a cantilevered slab edge that
extends beyond a thickened slab ring.
[0088] FIG. 33 is a detail that shows perimeter and radial post
tensioning in a foundation with a thickened slab edge.
[0089] FIG. 34 is a detail that shows a side view of a
prefabricated rib to a prefabricated perimeter beam connection.
[0090] FIG. 35 is a detail that shows a top view of a prefabricated
rib to a prefabricated perimeter beam connection.
[0091] FIG. 36 is detail that shows a rib being temporary supported
by a set of rib supports with through bolts extending through holes
in the ribs and removable and reusable assembly that connects to a
lower supports on sub-footings. Cotter pins are used to secure the
top assembly to the bottom support.
[0092] FIG. 37 is a plan view of an anchor bolt template fitted
with bolt holes matching that of the tower base flange and having
means for holding at least three leveling bolts with inserts.
[0093] FIG. 38 is a detail of the leveling bolts and corresponding
inserts during a concrete pour.
[0094] FIG. 39 is a detail of the leveling bolts and corresponding
inserts during leveling and grouting of a tower base flange.
[0095] FIG. 40 is a perspective view of the bottom segment of a
partially prefabricated offshore foundation ready to receive a
prefabricated metal or concrete stem atop the pedestal.
[0096] FIG. 41 is a perspective view of a completed partially
prefabricated offshore foundation with a prefabricated concrete
stem atop the pedestal. Vertical post tensioning elements with
marine grouting methods, such as grouted loop anchors are used to
connect the prefabricated stem to the pedestal.
[0097] FIG. 42 is an elevation view of an offshore foundation
during installation. The foundation is stabilized with ballast over
the base and inside the stem. Scour protection measures are added
around the perimeter of the base.
[0098] FIG. 43 is an elevation view of a foundation with a
prefabricated segmented concrete stem. The foundation is supported
by micro-piles or anchors.
[0099] FIG. 44 is a perspective view of the foundation comprising a
prestressed concrete base and a lattice steel tower with a wind
tower receiving adaptor at the top.
[0100] FIG. 45 is a perspective view of the foundation.
[0101] FIG. 46 is a perspective view of the foundation.
[0102] FIG. 47 is a connection detail of an L-shaped, prefabricated
perimeter beam to a cast-in-situ slab.
[0103] FIG. 48 is a perspective view of the prefabricated rib
foundation option showing the rebar before pouring the
concrete.
[0104] FIG. 49 is a perspective view of a foundation in with a
concrete stem extending above the foundation. The vertically
prestressed stem is made with prefabricated concrete segments or
cast in place concrete. This configuration is suitable for offshore
wind towers or hybrid concrete steel wind towers. The pedestal has
a solid core and the stem has a hollow core that can be filled with
ballast at the offshore installation site.
[0105] FIG. 50 is a perspective view of a foundation.
[0106] FIG. 51 is a perspective view of the foundation during
construction with slab concrete in place and the pedestal ready for
a concrete pour
[0107] FIG. 52 is a perspective view of the bolt assembly and
alignment apparatus.
[0108] FIG. 52a is the rod support for the bolt assembly and
alignment apparatus.
[0109] FIG. 53 is a plan view of the foundation showing different
groups of reinforcing and post-tensioning elements in the slab.
[0110] FIG. 54 is a perspective view of a prefabricated rib and
forms for forming the pedestal and slab.
[0111] FIG. 55 is an inner perspective view of a prefabricated rib
showing rib dowels and connections to the pedestal and the
slab.
[0112] FIG. 56 is a perspective view of the pedestal cage assembly
with anchor bolts and reinforcing cages around the anchor bolt
assembly.
[0113] FIG. 57 is a perspective view of a completed foundation.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0114] The present invention pertains to a wind turbine foundation.
The foundation comprises a plurality of components, namely a
central vertical pedestal, a substantially horizontal bottom
support slab, and a plurality of radial reinforcing ribs extending
radially outwardly from the pedestal. The ribs may be prefabricated
and transported to job site, but the pedestal and support slab are
poured in situ at the site out of concrete. Alternatively the ribs
may be cast in situ.
[0115] The present invention pertains to a fatigue resistant
foundation 100 for wind towers which comprises a plurality of
components, namely a central vertical pedestal 10, a substantially
horizontal continuous bottom support slab 20 with a stiffened
perimeter 21, a plurality of radial reinforcing ribs 16 extending
radially outwardly from the pedestal 10 and a three-dimensional
network of vertical 56, horizontal 110, 111, 112, diagonal 58b,
58c, radial 58 and circumferential 59 post-tensioning elements
embedded in the footing that keeps all the structural elements
under heavy multi-axial post compression, which reduces the stress
amplitudes and deflections and allows the foundation 100 to have a
desirable combination of high stiffness and superior fatigue
resistance while improving heat dissipation conditions during
construction by having a small ratio of concrete mass to surface
area thus eliminating the risk of thermal cracking due to the heat
of hydration.
[0116] A construction site is prepared by excavation, with
flattening and preparation of soil for the foundation 100. The
foundation 100 may be set on pilings 400, on piers 180, or have
anchors 404 (soil anchors or rock anchors 404 or micro-piles 401 or
other types) in a conventional manner.
[0117] The present invention ensures good contact between
foundation 100 and soil, or sub-base 14a, by casting.
[0118] The foundation 100 is cast against prepared soil, a crushed
stone sub-base 14a, a mud slab 14 or a membrane sheet in case of
offshore foundations assembled on a barge or in dry docks. Known
grouting and leveling techniques under precast elements can be
employed for ensuring plumb installation and good soil contact.
[0119] In one embodiment of the invention, the foundation 100 may
be set on a mud slab 14 or on compacted granular fill. The mud slab
14 is often a thin plain concrete layer intended to provide a clean
and level base for the foundation installation. After the
foundation site has been prepared, a plurality of three or more
precast stiffener ribs 16 are placed on the mud slab 14 or
compacted granular fill inside of the excavation pit 12. The
precast concrete stiffener ribs 16 may have means for leveling or
other leveling techniques can be employed for level and plumb
installation. If desired, grouting techniques can be used to ensure
complete rib base contact with the mud slab 14 or sub-base. The
precast concrete ribs 16 may have bases 21 with left shear key 38
and/or shear connectors and right shear key 36 and/or shear
connectors. The precast concrete stiffener ribs 16 may also have a
vertical shear key 34. The shear keys 34, 36 and 38 and associated
dowels 40, 42 and 46 are to ensure continuous connections, with
complete transfer of shear and bending loads, between the precast
concrete rib stiffener 16 and the cast in place concrete which is
to be poured into the foundation 100 to form the bottom support
slab 20. The precast concrete stiffener ribs 16 have upper dowels
40 and lower dowels 42 extending on the right and left sides of the
base 21 which interconnect with and spliced to upper mesh rebar 22
and lower mesh rebar 24 installed between the ribs 16 and connected
to dowels 40, 42 to form reinforcement for the slab 20 and pedestal
10 of foundation 100 when the concrete is poured. The rib 16 has
dowels 46 radially entering the pedestal 10 in the center of the
foundation 100.
[0120] Doweling of rebar between the ribs 16 and foundation
components can be achieved with rebar dowels extending from the
prefabricated elements or by using rebar couplers, bar extenders or
any mechanical rebar splicing system.
[0121] Arrays of grout or epoxy filled sleeves 42b arranged in the
slab 20 could receive corresponding arrays of vertical dowels 42a
extending from the bottom of prefabricated ribs 16 or perimeter
beams 190 or other prefabricated components.
[0122] Shear keys, or shear transfer mechanisms, can be replaced
with, or combined with, corbels or shear studs, or other shear
connectors such as angled rebar or embedded steel shapes 34a.
[0123] In another embodiment an array of steel beams 16s, are
encased into the web of the rib 16 and extend inwardly into the
pedestal cavity at the inner most end of ribs, and serve as a
suitable shear force transfer mechanism between the rib 16 and the
pedestal 10.
[0124] In another embodiment, the foundation 100 comprises a steel
frame 16f fully encased in concrete and has a central tower
receiving a metal cylinder 56b fixed to an array of radially
extending steel girders 16s encased in concrete beams 16, 21, 190
and rigidly connected at their outer ends to an array of perimeter
beams 190 encased in the concrete foundation 100 and a reinforced
concrete slab-on-grade 20 covering the foot print of the foundation
100 and connected to the steel frame.
[0125] In one embodiment the ribs 16 may be treated with concrete
bonding agent along surfaces where cast in place concrete is
received.
[0126] In another embodiment the foundation 100 may be provided
with drains 23 around the perimeter and the top surface of the slab
20 is slightly sloped towards the drains 23 such that water is
drained away from foundation 100.
[0127] In another embodiment, when foundations are installed in
sites prone to seismic activities and elevated water tables, the
slab may have holes to prevent soil liquefaction during seismic
events.
[0128] In another embodiment the ribs 16 or other foundation
elements may be covered or coated with protective material for
extending the life span of the footing.
[0129] In another embodiment the ribs 16 are placed on the mud slab
14 first and then the pedestal cage 50 made of an array of rebar,
preferably Z or C shaped rebar and circumferential rebar is
assembled around anchor bolt assembly 60 Alternatively the pedestal
cage 50 is assembled first or a preassembled pedestal cage 50
dropped into place first and then the ribs 16 with dowels 46 are
slid into place so that dowels 46 and shear connectors 34, 34a fit
between the elements of pedestal cage 50 rebar assembly.
[0130] The precast concrete stiffener rib 16 has lifting lugs 32 to
help place the stiffener rib 16 into the excavated construction
area. The base of the ribs may have a flat bottom surface such that
the ribs may stand on their own on the mud slab 14 or compacted
granular fill or during transportation from a precast plant to the
foundation site. The precast concrete stiffener ribs 16 have
prestressing elements 58 running through the ribs 16 radially from
the outside of the ribs 16 and through pedestal 10. The radial
prestressing elements 58 (or post tensioning elements) may be
anchored to the opposite side of the pedestal 10 or optionally run
through the opposing precast concrete stiffener rib 16 on the other
side of the pedestal 10 and anchored at the end of the opposite rib
16. Once the ribs 16 and the pedestal cage 50 are in place, the
dowels 46 extending radially inward from ribs 16 may be connected
to, or spliced with, corresponding dowels arranged in the pedestal
cage 50. Inside of pedestal cage 50 are additional rebar dowels 48
which will facilitate the continuity of the structural components
through the pedestal 10 as well as resist bearing, shear and
bending loads.
[0131] Also inside of pedestal reinforcement cage 50 is a bolt
assembly 60 comprising a bolt template 52 an embedment ring 54 and
anchor bolts 56 protected by a PVC sleeve 57 or wrapped with a
material to prevent bonding between the anchor bolts 56 and
concrete to be poured. The anchor bolts 56 have a top portion which
is used to attach the base flange 301a of a tower or column to the
pedestal 10. A grout trough template 52 at the bottom of the bolt
template 52 may be used to create a grout trough 90 to ensure a
good connection of the tower or column to the pedestal 10. The
grout trough 90 will be formed by removing the bolt template 52
from the anchor bolts 56 after the concrete has been poured. Radial
dowels 46, prestressing elements 58 or shear connectors 34 at the
inner end 16c of ribs 16 should be spaced to clear anchor bolts 56
and other reinforcement arranged in pedestal cage 50.
[0132] In a preferred embodiment, for fully cast in place
foundations, slab forms 17 may sit directly on the mud slab and rib
forms 16b are supported and kept elevated above slab 20 elevation
by means of adjustable and reusable support legs 16y arranged in
the rib forms 16b. Small footings or thickened mud slab areas could
be used under rib 16 form support legs. Pedestal forms 102 can be
supported by rib forms 16b or by separate support legs.
[0133] When ribs 16 are prefabricated, the bolt assembly 60 is held
in place and the anchor bolts 56 can be properly oriented by an
alignment apparatus 130. The alignment apparatus 130 has a central
post 132 with arms 134 attached perpendicularly to the center post
132 and having legs 136 for attachment to the top of the ribs 16 to
provide added stability and proper bolt template 52 alignment
during construction. The legs 136 have an adjustable height
relative to the arms 134. The arms 134 may have braces 138 attached
to the central post 132 for holding the arms 134 straight. The
central post 132 may also have central post support 135 to support
the central post 132. The alignment apparatus 130 also has
adjustable support members 140 for attachment between the arms 134
and the bolt template 52 to align the anchor bolts 56 so they are
upright. The alignment apparatus 130 can support the bolt assembly
60 without the central post 132 by relying on the legs 136
supported by ribs 16, which allows the lower portion of the central
post 132 to be removed if desired. Alignment apparatus 130 can be
used as a template to ensure proper location, elevation and
orientation of ribs 16.
[0134] The ribs 16 can be of any shape or size depending on the
specifications of the tower and loads thereon. For example the ribs
16 may be trapezoidal, rectangular, T shaped or I beam shaped. The
ribs 16 may have intermediate stiffener plates or diaphragms for
improved structural performance. The ribs 16 or rib forms 16b may
receive ramps or catwalks thereon for easy access to the forms
during construction.
[0135] Ribs 16, or rib forms 16b, may have means for receiving and
supporting perimeter forms 18, such as bolts or threaded inserts
for receiving and supporting the pedestal forms 102. The ribs 16,
or rib forms 16b, may also have attachment means 15 for holding
base forms 17. The pedestal forms 102 may be equipped with platform
sections for allowing access around the pedestal and the rest of
the footing.
[0136] With all the rebar 22, 24, ribs 16, pedestal 10, bolt
assembly frame 80 and optional alignment apparatus 130 in place
concrete forms may be attached such that concrete can be poured to
form the pedestal 10 and slab 20 of the foundation 100. Pedestal
forms 102 may attach to the ribs 16, or rib forms 16b, by bolts 18
or by any other means. Similarly the base perimeter forms 17 may be
attached to the ribs 16, or rib forms 16b, by bolts 15 or by any
other means. Alternatively the base perimeter forms 17 may be
supported to the ground or the mud slab.
[0137] With all the parts assembled all the rebar in place and the
duct for the prestressing tendons, or prestressing elements of the
foundation in place, concrete is then poured into the pedestal 10
and between the ribs 16. The pouring of the concrete can be
accomplished quickly and the slab areas between the ribs 16 can be
finished as the pedestal 10 concrete is still being poured. The
concrete may be used to build the pedestal 10 and the slab 20 in
one pour. Alternatively the base for the entire slab 20 foot print
of the footing can be poured in a first pour then the pedestal 10
can be formed in a second pour.
[0138] When a bonded multi-strand post tensioning system is used in
the foundation 100, the prefabricated components are fitted with
ducts and anchor hardware according to design specifications. The
cast in place components will be fitted with matching ducts to
facilitate the continuity of tendons across the foundation 100.
After the jacking of tendons, duct grouting is carried out as
required. If the un-bonded, bundled mono-strand system is employed,
no duct or grouting is required.
[0139] The structural load capacity of the foundation 100 is
increased significantly by the combination of radial 58 (or
diametric) and circumferential post tensioning 59. Circumferential
post tensioning 59 creates a desirable symmetric bi-axial post
compression in the slab 20. Circumferential post tensioning 59 is
applied at an elevation well below the neutral axes 16n of the ribs
16 thus creating eccentric post compression in the ribs 16 and the
pedestal 10 and resulting in increased nominal moment and shear
capacity of the ribs 16 as well as improvement in multi-axial
fatigue resistant of the pedestal 10, ribs 16 and the slab 20.
Radial or diametric post tensioning elements 58 extend from rib 16
to opposite rib 16 across the pedestal 10. Radial post-tensioning
is applied with an eccentric load pattern, with higher post
compression below the neutral axis 16n of the rib 16. When all the
prestressing elements are jacked, the foundation 100 is kept under
heavy multi-axial eccentric post compression stress, thus
increasing rib 16 structural capacity to resist soil support
reaction and providing low deflections, high stiffness and low
stress amplitudes resulting in high fatigue resistance and high
durability of the slab 20. Backfill 13 is added over the slab 20
for increased stability and stiffness of the foundation 100.
[0140] After the concrete sets, post tensioning is carried out and
the foundation 100 is backfilled with compacted granular fill 13 to
stabilize the foundation 100 against overturning.
[0141] Alternately, the bolt assembly 60 can be replaced by a tower
section 56b embedded in pedestal 10 concrete. The embedded section
56b having means 56c for receiving a tower base 301 by means of a
bolted connection arranged at the top of the section 56b The
embedded metal cylindrical tower section 56b encased in pedestal 10
concrete is provided with holes 56h for rebar and post tensioning
tendons 58 to extend through the metal cylinder 56b. Post
tensioning 58 tendons can extend through holes 56h arranged in the
cylinder and across the pedestal 10, through the ribs 16 to be
anchored on distal ends of the foundation.
[0142] Pedestal 10 can be any size or shape, round, triangular,
square, polygon or other shape depending on the specifications of
the tower and loads thereon. The ribs 16 can be in any pattern
around the pedestal 10. In one embodiment shown in FIGS. 49, 50 the
foundation 100 may have a square pedestal 10 and ribs 16 at the
corners parallel to the faces of the pedestal. The pedestal 10 may
have a stepped construction with an enlarged lower cross section to
reduce the length of the cantilevered ribs 16.
[0143] Pre-assembled reinforcement sections (meshes) of the slab 20
components can be lowered into place in the slab 20 to speedup
construction. All rebar dowel or metal shear connectors extending
through construction joints may be galvanized or Epoxy coated to
prevent corrosion. The use of mechanical couplers in the foundation
100 may be limited or avoided. Specified mechanical couplers must
be tested and certified for the number of load cycles in the life
span of the foundation 100.
[0144] In another preferred embodiment, the ribs 16 are cast in
place in reusable rib forms 16b. The ribs 16 are cast in place
jointly with the pedestal 10 in one continuous pour over the slab
20. Optionally, the ribs 16, the pedestal 10 and the slab 20 are
all jointly cast in one pour. All rib internal components including
rebar assembly with dowels and prestressing elements are placed
inside the forms, then cast in place concrete is poured into the
rib forms 16b as well as into pedestal 10 and slab 20 forms.
[0145] Rib reinforcing cages 16rc can be assembled above grade and
lowered into the foundation in one or more sections.
[0146] In a preferred embodiment, rib forms 16b with internal rib
reinforcing cages 16rc are preassembled and lowered into the
foundation by cranes to mesh with slab reinforcing sections 22, 24
already placed in the foundation. The radial reinforcing pattern 22
of the slab 20 enables the meshing rib dowels 42 between slab
reinforcing 22, 24 without geometric interference.
[0147] Ribs 16 can also be made in segments 16sg and eventually
united by means of doweling or by using segmented post-tensioned
construction techniques. Rib anchor zone 16x with anchor trumpets
16t and hardware can be prefabricated separately of higher strength
concrete than the rest of the rib 16.
[0148] As shown in FIGS. 35 and 47, prefabricated perimeter beams
190 with post tension ducts 112 may serve as perimeter forms and
become part of the structure. An array of precast, rectangular or
L-shaped beams 190 with means for connecting to the slab 20 and the
ribs 16 can be used in the foundation perimeter construction. The
perimeter (edge) beams 190 can rest directly on the mud slab and
connect to the slab 20 using horizontal dowels and shear keys
arranged on the inner side. Optionally the perimeter beam 190 is
elevated and connects to the top of the slab 20 using dowels 190b
extending from the bottom of the perimeter beams 190 The precast
perimeter beams 190 may have dowels 190b and shear keys 192 (such
as corrugations) extending from their sides ends for connecting to
the ribs 16. In this case the ribs 16 will have corresponding
dowels 45 and shear keys 16sh for receiving and supporting
perimeter beams 190. The connection between ribs 16 and perimeter
beams 190 is established using closure pours in small cavities at
the conjunctions of the ribs 16 and the perimeter beams 190.
[0149] The foundation 100 pertains to a hybrid gravity based and
rock anchored foundation. Ribs 16 can be made with arrangement,
mechanisms and connecters for receiving piles 400 or micro-piles
401 or anchors 404 in different configurations. Vertical through
holes 16g in the ribs 16 can provide means for receiving a pile
400, micro pile 401 or an anchor 404. Bearing elements 404b and
grouting are arranged on top of each rib 16 to establish the
required structural connection. An array of bearing plates 404b
with tensioning nuts 404c on each soil/rock anchor may be used to
compress the foundation 100 against supporting soil. Vertical
through holes 16g with corrugations 404h for the anchor 404 extend
through the foundation 100. Bearing plates 404b with tensioning
nuts 404c can be placed on top of the pedestal 10 or in the
foundation 100. If desired ribs 16 may have piers 180 extending
vertically from the ribs 16 and the top of the pier elevation is
raised to a higher elevation to make anchor bolts 404a accessible
for tensioning and testing. Typical rock or soil anchor
construction and grouting methods can be utilized. Another option
is to house rock anchor bolts 404a and bearing plates 404b and
tensioning nuts 404c in accessible corrosion protection
compartments above the foundation 100.
[0150] In another embodiment as shown in FIG. 43 and FIG. 44, the
invention pertains to a foundation 100 that comprises the following
elements: [0151] 1 A vertically extending pedestal 10 that is cast
in situ, out of concrete, the pedestal 10 serving to receive and
support the tower structure; [0152] 2 A substantially horizontal
support slab 20 that is cast in situ out of concrete, the support
slab 20 covering an area of ground larger than that covered by the
pedestal 10; [0153] 3 A plurality of radial ribs 16 extending
radially outwardly from the pedestal 10 and spaced around the
pedestal 10, each rib being joined along the base thereof to the
support slab 20 and being joined along an inner side thereof to the
pedestal 10, each rib has means for receiving a rock or soil
anchor; [0154] 4 An optional plurality of perimeter beams 190, or
stiffened slab edge 21, spanning continuously, near the perimeter
of the foundation 100p, between ribs 16 and supporting the slab 20
may be employed; [0155] 5 An array of soil or rock anchors 404
extending through the foundation 100, preferably through the ribs
16, may extend down into the ground below the foundation, each
anchor having a bearing element 404b in or above the foundation 100
and compressing the foundation against support soil when the
anchors are tensioned. [0156] 6 Optionally the anchor can be
grouted into the ground to function as a pile anchor.
[0157] The prefabricated components can be molded at a facility
under controlled conditions for good quality concrete setting and
controlled rebar spacing which is superior to what can be obtained
on a job site and at a lower cost. The ribs 16, acting as deep
stiff horizontal cantilever support, allow the base of the
foundation slabs to have a relatively small thickness using less
cast in place concrete and rebar thus lowering the cost for each
foundation.
[0158] Alternatively, as shown in FIG. 36 ribs 16 may have reusable
temporary supports 16y, or other means, arranged at the ribs 16 to
hold the ribs 16 in place, maintain them plumb during construction
and elevate them at a predetermined height over slab reinforcing
22, 24. This style of ribs 16 is intended to be raised above the
ground or mud slab 14 so that the foundation support slab 20 can be
poured in place continuously under ribs 16. Dowels 42 and shear
connectors for this style may be arranged at the bottom of the rib
16 for connecting with base slab 20 which extends under the raised
rib 16. When the concrete cures the continuous support slab 20,
extending under the ribs, is united to the prefabricated ribs 16
and the ribs 16 are also united to the pedestal 10. The rib inner
ends 16c will be partially encased in the pedestal 10 to increase
rib torsional end resistance. The final result is a continuous
monolithic foundation wherein loads are carried across the
structure vertically and laterally through the continuous structure
by the doweled and spliced reinforcing steel bars which are
integrally cast into the pedestal 10, ribs 16 and support slab 20.
The combination of the high stiffness of the ribs 16, solid
pedestal 10 and continuous slab 20 construction across the pedestal
10, and under ribs 16, allows the slab 20 to behave structurally as
a continuous slab 20 over multiple rigid supports resulting in
small flexural and shear stresses in the slab 20, reducing
deflections, improving fatigue conditions and increasing the
stiffness of the foundation as well as allowing for the benefits of
an economical design.
[0159] Cast in situ concrete can be shielded from extreme weather,
including heat, cold, rain and snow, by simply extending blankets,
covers or shields between ribs 16 during construction, and then
using heaters or fans as required to regulate the temperature and
humidity of the concrete to allow for proper setting and curing
conditions.
[0160] Another embodiment of the present invention pertains to a
leveling technique that simplifies the tower base leveling process
and shortens the number of steps required for grouting under a
tower base. The bolt template 52 is provided at the very top of the
bolt assembly 60 with at least three sets of additional bolts 53
and corresponding threaded bolt inserts 53b suitable for embedment
in the concrete. Such leveling bolts 53 and inserts 53b will be
located outside or inside the bolt circle 60a of tower base, but
directly under tower base flange 301a. This allows for continuity
of grout bed 90a construction and provides an easy access to
leveling bolts 53. Small cutouts at leveling bolt locations may be
used. Another benefit of this leveling technique is having the
ability to apply continuous grout bed 90a that is free of cold
joints, under the tower base flange 301a in one session as well as
having the ability to tension all anchor bolts 56 in one work
session.
[0161] In another embodiment the onshore foundation may have a
pedestal 10 that is rigidly connected to vertical concrete stem 11
that is fixed to a tower base of a wind tower. The pedestal and the
stem are vertically prestressed with vertical post tensioning
elements extending through the height of the foundation. The stem
is fitted with an array of bolts 60 for receiving and supporting
the tower base 301.
[0162] The foundation design, as shown in FIG. 44, can be
reconfigured to support lattice towers 200 comprising multiple
columns connections to foundations in a spaced array. The ribs 16
will be provided with column receiving components including
embedded anchor bolts (or grouting around an embedded element) and
an integral pier design into the rib 16. The rib geometry may be
widened and enlarged at the integral pier 180. The array of said
integrated piers ribs 16 are fitted with means for receiving and
supporting the legs or the columns 200a of the lattice tower
200.
[0163] The integral piers 180 can extend above final grade
elevation, while the top of pedestal 10 may stay below final grade
elevation. For this foundation style, pedestal elevation may be
depressed and tower receiving components may not be required in the
pedestal 10. This configuration may also be used in offshore
applications wherein a prefabricated gravity foundation 100 is
connected to lattice tower structure 200 that is fitted with a wind
tower receiving component at its top. The foundation 100 will be
installed over prepared seabed and filled with a suitable
backfilling material 13, and surrounded with scour protection
13b.
[0164] As shown in FIG. 45, in permafrost conditions, the
foundation 100 may be supported on an array of concrete piers
deeply embedded and frozen into the ground. Anchor bolts 404a can
be used to secure the ribs 16 to their supporting piers 402 around
the perimeter of the foundation 100p. The slab 20 bottom elevation
set above grade elevation. Alternatively the slab may not be used
in the design.
[0165] In another embodiment as shown in FIG. 1, the invention
pertains to a fatigue resistant gravity based spread footing for
use under heavy multi-axial cyclical loading of a wind tower 300
which comprises a plurality of components, namely a central
vertical pedestal 10, a substantially horizontal continuous bottom
support slab 20 with stiffened perimeter 21, a plurality of radial
reinforcing ribs 16 extending radially outwardly from the pedestal
10 and a three-dimensional network of vertical 60, horizontal 110,
111, 112, 58, diagonal 58b, 58c, radial 58 (or diametric) and
circumferential 59 post-tensioning elements that keep the
structural elements under heavy multi-axial post compression with
specific eccentricities and orientations that are intended to
reduces stress amplitudes and deflections and allows the foundation
100 to have a desirable combination of high stiffness and superior
fatigue resistance while improving heat dissipation conditions
during construction by having a small ratio of concrete mass to
surface area thus eliminating the risk of thermal cracking due to
heat of hydration.
[0166] Vertical prestressing of the pedestal 10 can be carried out
independently of tower receiving elements. A pedestal 10 may have
an array of vertical post tensioning elements 56 that does not
connect to a tower 300, and an embedded tower section 56b bolted to
a tower structure 300.
[0167] Radial post-tensioning 58, extending across the foundation
100, in pairs of ribs 16, allows for the desirable structural
continuity and the direct transfer of loads from downwind ribs 16
into the pedestal 10 and then into the opposing upwind ribs 16.
Radial and circumferential post compression stresses in the slab 20
and/or perimeter beams 190 allows for a desirable reduction in
stress amplitudes the structural continuity between slab 20 spans
and/or perimeter beam 190 spans, across the ribs 16, thus creating
a desirable load sharing mechanism between adjacent ribs 16 by
forcing more ribs 16 to be engaged in resisting tower loads.
[0168] The invention pertains to a durable, high-stiffness,
fatigue-resistant foundation structure 100 for onshore wind tower
installations which comprises: [0169] 1. a central pedestal 10 that
is made of cast-in-place concrete with concentric vertical
prestressing elements 56, 70 and eccentric multi-axial horizontal
and/or radial post-tensioning elements 58a, 58b, 58c; [0170] 2. an
array of cast-in-place eccentrically post-tensioned radial ribs 16;
[0171] 3. a cast-in-place slab 20 with heavily post-tensioned
thickened slab edge 21.
[0172] All components are made of high strength reinforced concrete
and are rigidly connected to each other to behave as a monolithic
spread foundation structure. The structural components are rigidly
connected with arrays of rebar dowels 42, 46 (passive reinforcing)
and/or post-tensioning elements extending through the conjunctions.
The slab 20 functions as a two-way slab system that is free of
construction joints across the footprint of the foundation and
spans continuously over multiple ribs 16. Perimeter post tensioning
59a or circumferential post tensioning 59 of the slab 20 is applied
at an elevation well below the neutral axes 16n of the ribs 16 to
cause eccentric loading of the ribs 16 and the pedestal 10. Radial
post-tensioning elements 58 with an eccentric load pattern, with
higher post compression at the bottom of the rib, extend from rib
end 16x to the opposite rib end 16x across the pedestal 10, or to
the opposite end of the pedestal 10. When all the prestressing
elements are jacked, the foundation 100 is kept under heavy
multi-axial eccentric post compression stress, thus increasing rib
16 structural capacity to resist soil support reaction and
providing low deflections, high stiffness and low stress amplitudes
resulting in high fatigue resistant and high durability. Backfill
13 is added over the slab 20 for increased stability and stiffness
of the foundation 100.
[0173] Soil support reaction under the slab 20 is transferred from
the slab 20 to the ribs 16 and thickened slab edge 21 (or perimeter
beams 190) as in two-way slab systems with more load distribution
going to the ribs 16 in the primary span. Perimeter 112 or
circumferential 59 post-tensioning is applied, generally in the
orientation of the primary span that effectively reduces stress
amplitudes and deflections in the slab 20 by keeping the slab 20
under heavy post-compression in the directions of primary slab
spans 20s1, and secondary slab span 20s2 around the foundation. The
size, distribution, eccentricity and location of post tensioning
elements 58 in the ribs 16 and the slab 20 are used to dictate the
natural frequencies of the foundation 100 to be in a safe range
relative to operating frequencies of the wind generator according
to turbine manufacturer recommendations.
[0174] The 3-dimensional post-tensioning network in the foundation
keep all the structural components (Pedestal 10, ribs 16, slab 20,
thickened slab edges 21 (or integral edge beams)) under multi-axial
post compression confinement resulting in lower stress range
amplitudes thus yielding higher stiffness, more effective crack
control, lower deflections and improved fatigue resistance.
Superior fatigue resistance and long life-span are achieved by
keeping most of the structural elements of the foundation 100 under
multi-axial compression while resisting operating loads or even
during normal and abnormal extreme loads from the supported
structure (wind power generator).
[0175] In a preferred embodiment, rib post-tensioning requirements
are reduced by engaging fully developed bar dowels 46 from the rib
16 into the pedestal connection as well as extending fully
developed radial rebar dowels 22r, 24r of the slab 20 into the
pedestal 10, thus allowing passive reinforcing to participate in
the connection especially under extreme loads. A radial slab
reinforcing pattern with tapered rib width is very cost effective
as the rib 16 to pedestal 10 connection benefits from a large
number of top and bottom radial slab reinforcing bars 22, 24
participating in said connection as the rib width widens, thus
reducing the number of bottom post-tensioning strands 58a required
for the connection.
[0176] The structural configuration of the foundation 100 reduces
the overall cumulative deflections in the structure under tower
loads and significantly improves the rotational stiffness of the
foundation 100 which is a key factor in determining the size of
foundations in wind turbine installations. The rotational stiffness
is also improved by the interlocking between the surrounding soil
(after backfilling) and the multiple surfaces and vertical faces of
the foundation structure. The horizontal stiffness is improved by
the passive earth pressure on the multiple surfaces of the
structure. Both rotational and horizontal stiffness achieved by
this design are much higher than conventional tapered inverted-T
gravity spread footings especially for onshore foundations
installed below grade in an excavated pit because of the increased
interlocking surface area and increased passive earth pressure and
increased friction on the multiple faces of the fatigue resistant
foundation 100.
[0177] The solid-core pedestal 10 comprises a continuous
reinforcing cage 50 and a tower receiving component 56, such as
anchor-bolt assembly 60, with a cylindrical array of bond protected
high strength post-tensioning bolts 56, for connecting to wind
tower base flange 301a. In another embodiment and the tower
receiving component may comprise an embedded cylindrical metal
tower section 56b with means 56c for connecting to a tower section
such as a flange 56c with bolt holes 56d for receiving bolts 301b
at its top and with an array of holes 56h to allow the passing of
rebar 46 and post tension tendons 58. The embedded tower section
56b is also fitted with conventional bearing flanges 56e and ring
stiffeners for interlocking with the pedestal concrete. The anchor
bolt assembly 60 ensures structural continuity between the tower
300 and the pedestal 10. The post-tensioning forces of the anchor
bolts 56 are selected to insure that the tower base flange 301a
remains in contact with the pedestal 10 under extreme normal and
abnormal load conditions. The bolt assembly 60 includes, at its
bottom end, a bearing element 54 that may consist of an embedment
ring plate 54 that is made of segments that are welded
together.
[0178] As shown in FIGS. 7 and 26, radial post-tension tendons 58
and rebar reinforcing elements 46 extending from the ribs 16 and
the slab 20 pass through the pedestal reinforcing cage 50, or
through holes 56h in the embedded metal tower section 56b.
[0179] As shown in FIG. 17-22, post-tensioning elements 58, 58a,
58b, 58c are flared horizontally, profiled vertically, arranged in
matrix groups, spaced and draped in a manner that allows for
optimum utilization of post-tensioning and ease of installation
while avoiding tendon congestion and stress concentrations as
tendons 58, 58a, 58b, 58c crisscross in the pedestal 10. The
regrouping of tendons to form a flat and wide matrix along each
axis was found to be effective in avoiding tendon congestion
especially in the pedestal 10. The flat and wide matrix of tendons
are placed as high or as low as possible to maximize their moment
arms and optimize their contributed moment capacity. For corrosion
protection, bonded (multi-strand and grouted) or un-bonded
encapsulated (mono-strand) post-tensioning elements and their
associated construction techniques can be used in the foundation
100.
[0180] The rib's thickness 16th can be gradually increased at the
connection to the pedestal 10 to increase rib flexural, shear and
torsional capacity and enhance pedestal confinement 16m. The
post-tensioning requirements can be reduced by engaging dowels 46
at the rib-to-pedestal connection and by extending fully developed
radial dowels 46, 22r, 24r from the rib 16 and the slab 20 deep
into the pedestal 10, thus allowing passive reinforcing to
participate in the connection.
[0181] In another embodiment, as shown in FIG. 2, ribs 16 top
surface can be tapered to a substantial slope extending vertically
to an elevation near the top of pedestal 10 allowing the ribs 16 to
benefit from diaphragm action at their inner zone and also provide
lateral support for the full height of the pedestal 10 and to
provide concrete confinement at the highly stressed zone at the top
of pedestal 10 under tower base flange 301.
[0182] The foundation may have a circular or polygonal foot print.
The thickened slab edge 21 (or perimeter beam 190 may extend above
or below the foundation. A shallow perimeter beam 190 profile
should be selected for ease of backfilling and improved
accessibility for roller compactors during the backfilling of the
foundation 100. A thickened slab ring beam 21 may be designed to be
at an offset distance away from the slab edge allowing the slab
segment, outside the ring, to behave as a cantilever. This
configuration reduces slab 20 span and deflections as well as the
volume of concrete required in the foundation 100.
[0183] As shown in FIG. 5, the configuration of the slab 20 and its
continuous reinforcing including that of the thickened slab ring
beam 21 is configured to create a rigid composite connection to the
ribs 16 with high stiffness which is sufficient to allow adjoining
ribs 16 to participate more in resisting the loads and thus
reducing local deflections and increasing overall foundation
stiffness in addition to reducing the unsupported length of
cantilever radial ribs 16.
[0184] In a preferred embodiment, as shown in FIG. 13, the pairing
of the ribs 16 on distal ends 10x and the continuous perimeter beam
21 construction yield a cost effective layout of post-tensioning
that uses a small number of tendons and corresponding anchors 59b
as well as reduces friction losses by avoiding sharp turns in
tendon layout. The tendons 58 of the ribs 16 are anchored in a
matrix array 58m at the outer end of the rib 16 and extend
horizontally and diagonally along the rib 16 to split into at least
two groups 58a and 58b one near the bottom and the other near the
top of the rib as it connects to the pedestal 10. The tendons 58
are more concentrated at the bottom than at the top in a concentric
prestressing pattern 58m1 that is intended to maximize the
structural capacity of the foundation and meet the flexure and
shear demand of the governing load cases.
[0185] Ribs 16 may have thickened flanges, at their connection to
the pedestal 10 that may also house post tensioning anchors for
tendons 58 extending from ribs 16 on the opposite side of pedestal
10. The ribs 16 may also have post tensioning anchors along their
sides or tops if tendon curtailment methods are applied in the
design. The ribs 16 may also have embedded loop anchors if looping
of tendons is used in the design. Loop anchors 70 could also be
used in the pedestal 10 to support and vertically prestress precast
concrete towers 300b, or concrete stems 11.
[0186] As shown in FIG. 21, the tendons 58 in ribs 16 extend
horizontally and diagonally to be split into three distinctive
groups as they enter the pedestal 10. The first group 58a with more
tendons is placed at the bottom of ribs 16 or in the slab 10 to
create camber for reducing deflections and improving foundation
soil contact as well as meet the high flexural demand from the
governing load cases, and the second group 58b has a slope up
diagonally to follow the geometry of the top of the rib as they
enter the pedestal 10. The third group 58c is in the middle and it
starts horizontal at rib anchor block 16an and diagonally slopes
down towards the bottom of the rib 16 to enter the pedestal 10 for
optimum use of the tendons 58. Tendons 58 in the pedestal 10 are
fanned and flared into groups in a flat pattern 58m2 to simplify
the installation and maximize their utilization by increasing their
effective depth or moment arms measured from the top or the bottom
of the structural concrete. Additional post-tensioning groups for
shear resistance can be provided by providing tendons 58 that
traverse the shear failure plane in the ribs 16.
[0187] In another embodiment, as shown in FIG. 21, the
post-tensioning in the ribs 16 consist of three distinctive groups:
[0188] 1. A bottom group of tendons 58a that is horizontal at the
bottom of the rib 16 and in the slab 20 and may be grouped with
slab post tensioning, [0189] 2. A top group of tendons 58b that is
diagonally sloped upward to follow the geometry of the rib top,
[0190] 3. An optional middle group of tendons 58c that starts
horizontal at rib outer edge 16x and is diagonally sloped down
towards the bottom of the rib 16 to eliminate dead load deflections
and keep the ribs 16 and pedestal 10 under post compression during
normal operating conditions and also provide the high demand of
post-tensioning capacity required at the bottom of the rib 16 for
downwind load cases, and traverse the shear failure plane for ribs
16 in the governing downwind load cases and provide additional
shear resisting capacity in each rib 16, such that the number of
strands in the bottom of the rib 16 and the pedestal 10 is much
higher than that at the top thus causing a multi-axial, heavy,
eccentric horizontal post compression in the foundation after all
the tendons 58 are jacked.
[0191] Alternately, as shown in FIG. 13, anchor-blocks for
perimeter or circumferential post-tension tendons can be placed at
perimeter beams 190, (ring beams 21) at the thickened slab, at the
edge of the foundation on top of perimeter beams 190 or on the
sides of ribs 16. A preferred layout with two anchor blocks 21a on
opposite sides of the foundation and with a semi-circular
(180-degree) tendon arrangement is shown in FIG. 13. Ring tendons
59 with ring anchors 59b (such as dog-bone anchors) can be used,
with perimeter or circumferential tendons, to avoid having blisters
on the foundation 100. Styrofoam block-outs 53a can be placed in
the foundation 100 according to anchor manufacturer recommended
dimensions. When the concrete reaches the sufficient strength ring
tendons 58 are jacked and ring anchors 59b grouted.
[0192] In another embodiment circumferential post tensioning may be
made with multiple tiers of tendons 59, in this case anchor block
21a locations or ring anchor 59b locations for each tier may be
staggered around the perimeter of the foundation 100p to reduce
stress concentration. Corrosion protection must be provided at
anchor locations. Perimeter post-tensioning 112, or circumferential
post-tensioning 59 can be made with bundled, un-bonded mono-strands
without encapsulation.
[0193] The foundation may be made with a network of prestressed
concrete elements that can be structurally analyzed, with the strut
and tie method. A three-dimensional structure made of an array of
vertically and horizontally oriented truss-girders joined at the
center may be used, with major tension chords reinforced with
prestressing tendons, based on both upwind and downwind load cases.
The tension forces in the structure are resisted largely by
prestressing elements and passive reinforcing. Compression forces
are resisted largely by the concrete elements. The structure can be
analyzed as a circumferential array of vertically oriented trusses
that are fixed at their inner ends 16c to the central pedestal 10
and are laterally stabilized at their bottom by a horizontal
trussed diaphragm formed by perimeter post tensioning 59a, in the
slab 20 or perimeter beam 190, and radial bottom tendons 58 in the
ribs 16 or the slab 20.
[0194] In another embodiment, as shown in FIG. 1, the fatigue
resistant foundation 100 comprises a circumferential array of
vertically oriented eccentrically prestressed cantilevered girders
16 that are fixed at their inner ends 16c to a central pedestal 10
that is laterally supported and confined through most of its height
by rib concrete, and the ribs 16 and pedestal 10 are laterally
stabilized at their bottom by a horizontal prestressed concrete
trussed diaphragm, with a continuous slab 20, and the prestressing
is provided by radial tendons 58 in the ribs 16 (or the slab 20)
and circumferential post tensioning elements 59. The radial 58, and
circumferential 59 tendons provide eccentric prestressing in the
ribs 16 and the pedestal 10. The pedestal 10 is vertically
prestressed by an array of vertically extending anchor bolt circle
60 and is structurally fixed to a tower base 301 of a pylon. The
slab is prestressed with tendons 110, 111 and 112 and
circumferential tendons 59.
[0195] In another preferred embodiment the construction of the
foundation 100 may utilize pre-assembled slab perimeter reinforcing
cages 21c, built in segments with overlapping spliced bars at their
ends, and each having an array of shear resisting vertical ties
21vt and flexure resisting horizontal bars 21h as well as anchor
zone reinforcing. Slab perimeter cages 21c or perimeter beam
reinforcing cages, 190c can be preassembled and then placed in the
foundation.
[0196] As shown in FIGS. 4, 5 and 6, the foundation has specific
reinforcing groups. The ribs 16 have flexure reinforcing tendons 58
concentrated at the bottom and the top, vertical stirrups 16vt for
shear reinforcing tightly spaced in high shear zones along rib
inner end 16c, rib skin reinforcing on each face 16fs and bursting
and splitting reinforcing made of horizontal hairpins 16hp
extending between the rib skin reinforcing 16fs, as well as
straight, hooked or U-shaped horizontal dowels 46 for embedment
into the pedestal 10 and vertical dowels 42, at the bottom of the
ribs 16 are used, for composite action with the slab 20. As shown
in FIG. 4, the vertical stirrups 16vt also function as dowels for
composite action of the slab 20. The dowels may be spaced such that
they mesh between slab reinforcing bars without geometric
interference. The rib reinforcing 16rc is built in preassembled
cages and placed over the slab reinforcing 22, 24. In order to
maximize shear capacity vertical stirrups 16vt are placed
side-by-side, in pairs, at the inner rib zone 16c where the shear
demand is high.
[0197] Anchor zones, as shown in FIGS. 5, 6, 21, 22, are provided
with heavy reinforcing with trim bar and ties 16tt as well as
surface reinforcing at the anchor block location. The ribs 16 may
also have horizontal reinforcing dowels 45, perpendicular to the
ribs 16, to facilitate the structural continuity of the supported
perimeter beams 190 or the thickened slab 21, across the width of
the rib 16, by means of splicing the dowels 45 with perimeter
reinforcing 21c, 190c.
[0198] The pedestal 10, as shown in FIG. 11 and FIG. 12, has a
horizontal mesh 50t at the top and skin reinforcing 50c1 at all
surfaces as well as at least one cage 50, around the anchor bolt
assembly 60, comprising vertical tightly meshed bursting
reinforcing 50c including two cylindrical meshes 50c1 & 50c2
confining the anchor bolts 56 each comprising horizontal hoops
50c1h & 50c2h and either C or Z-Shaped bars 50cv and a radial
array of horizontal hair-pins 16hp or stirrups tying both
cylindrical meshes 50c1 & 50c2 or spiral stirrups each housing
a number of anchor bolts 56. The pedestal 10 cage assembly may
comprise two concentric tightly meshed cages 50c1 & 50c2
surrounding the anchor bolts 56 one from the inside and the other
from the outside with a radial array of bursting and splitting
resistant hairpins 16hp extending between the two cages 50c1 and
50c2. Additionally an array of vertically oriented pedestal 10
vertical bursting out of plane stress resistant reinforcing group
of reinforcing elements, comprising circumferentially spaced
vertical hairpins 50vt extending between said top horizontal mesh
50t and a horizontal bottom reinforcing mesh 50b in the pedestal 10
or slab 20, is included in the pedestal cage 50. The vertical
hairpins 50vt in pedestal core 10a also function as supports to
secure tendons in the pedestal 10 during construction.
[0199] Upper 22 and lower 24 slab reinforcing meshes may have any
pattern such as a square grid, a circular array with radial pattern
or overlapping pie-shaped segments. Additionally, there may be an
array of slab reinforcing 22, 24 locally arranged beneath the ribs
16 oriented parallel to the ribs 16 and extending into the pedestal
10 to facilitate composite action. The slab 20 may also be
reinforced with post-tensioning elements in any pattern including
radial, circumferential, perimeter or a square grid.
[0200] The foundation may utilize many prefabricated components
including rebar meshes and cages, pedestal cage assembly, pre cut
post-tensioning strands, preassembled post-tensioning bundles,
pre-cut post-tensioning duct sections and prefabricated concrete
forms.
[0201] Reusable rib forms 16b may be utilized to form the
foundation perimeter 100p, the ribs 16 and the pedestal 10. Forms
can be made to be segmented, universal, expandable and adjustable
to work for different foundation sizes. Rib forms 16b can be made
with adjustable supports 16y to elevate the forms above the wet
slab 20 concrete during construction if the foundation is built in
one pour. Rib forms 16b may sit directly on the hardened concrete
slab 20 if the foundation is built in two pours. Rib forms 16b may
be made with two side-panels of stiffened non-stick plates and an
array of adjustable horizontal spacers between the panels to
maintain proper geometry and resist the lateral pressure of wet
concrete. Rib forms 16b and pedestal forms 102 may be fitted with
lifting lugs 32 or means for receiving and supporting ladders,
catwalks 95 and work platforms 95 to allow for access around the
foundation 100. The forms may have means for securing post-tension
anchors and hardware at specific spacing during construction. The
forms may also have means for hanging and supporting rib
reinforcing cages.
[0202] The foundation 100 may be supported on piles 400, or
micro-piles 401 or piers 402 or rammed-aggregate piers 405. The
foundation 100 may receive rock (or soil) anchors 404 in a
conventional manner.
[0203] A construction site is prepared by excavation, grading and
compaction soil for the foundation. The foundation 100 may be set
on a mud slab 14 or on compacted granular fill. The mud slab 14 is
a thin plain concrete layer intended to provide a clean and level
base for foundation installation.
[0204] In one embodiment, as shown in FIG. 48 after the foundation
site has been prepared, the slab reinforcing 22, 24 is placed
inside slab forms 17 and the slab 20 is poured in place with dowels
42 extending up from the slab 20 to receive the ribs 16 and the
pedestal 10 in a second pour. The rib rebar 16fs and pedestal rebar
50 and cage 60 placement with post-tension tendons 58 (or duct)
placement are set in place rib forms 16b and pedestal forms 102 are
installed before a second pour is carried out. Alternatively the
foundation 100 can be poured in a single pour with the use of
accelerators in the concrete mix and by following a well designed
concrete pour sequence. A set of small footings 16f, placed within
the mud slab, can be used to support and elevate the rib forms 16b
and pedestal forms 102 during construction. Slab 20, pedestal 10
and rib 16 reinforcing elements are assembled in the foundation
100. Forms are placed in the foundation around the perimeter, the
ribs 16 and the pedestal 10 and the concrete is poured into the
foundation 100 in a carefully designed pour sequence. One option is
to start with slab 20 and the bottom part of the ribs 16 and the
pedestal 10 with accelerator in the concrete mix to seal the bottom
of rib 16 and pedestal forms 102 by the time the slab 20 concrete
is finished, the ribs 16 and the pedestal 10 are poured jointly in
small lifts.
[0205] When the concrete hardens to a specific strength, the
post-tension elements are jacked and grouted as required. The tower
base flange 301 is then attached to the pedestal 10 and grouted,
and the tower anchor bolts 56 are tensioned after the grout reaches
sufficient strength.
[0206] In a preferred embodiment, as shown in FIG. 13, the
invention relates to a high stiffness, fatigue resistant, wind
turbine foundation 100, supporting a wind generator with a
multi-megawatt rating and subjected to extremely high cyclical
upset loads that comprise the following components comprising:
[0207] 1. a substantially wide central pedestal 10 with
substantially solid core concrete construction 10a that is kept,
through most of its height, under a combination of lateral
structural concrete ribs 16 and confinement 16m, high vertical
post-compression stress and high eccentric multi-axial lateral
horizontal post-compression stress across its width, provided by
said lateral ribs 16 and post-tensioning elements 58 that traverse
the width of the pedestal 10, through non-segmented concrete
construction, along multiple axes in a concentric pattern, and
having a set of upright, circumferentially spaced anchor bolts 56,
for providing the high vertical post-compression stress, extending
through said pedestal 10, and having lower ends anchored to an
anchor ring and upper ends projecting upwardly from said top end of
said pedestal, said anchor bolts 56 being substantially bond
protected along their length, said upper ends of said bolts 56
project upwardly from the pedestal 10 through a base flange 301a of
an annular tower 300 structurally fixed atop the pedestal 10, and
also having an upright heavily reinforced cage of tightly meshed
rebar, and concentrically arranged around both sides of the anchor
bolt cage with an opening to allow the passing of lateral load
transfer elements 58, 46, [0208] 2. a support slab-on-grade 20,
cast-in-situ out of concrete against the soil, in an excavation pit
12, of continuous construction and covering a footprint
substantially larger than that of the pedestal 10 and having a
thickness that is much smaller than the depth of the pedestal 10
and having a thickened edge 21 made of concrete integral with the
support slab 20 and having horizontal post-tensioning elements 58,
59, 110, 111, 112 to keep the slab 20 under heavy multi-axial post
compression, [0209] 3. an array of concentrically arranged ribs 16
made of deep girder construction, integral with the pedestal and
support slab 20, and jointly cast-in-situ with said pedestal 10,
and extending vertically, above the slab 20, to an elevation near
the top of pedestal 10 such that the pedestal 10 is laterally
supported and substantially confined below the tower base flange
301, the ribs 16 having a width that is substantially smaller than
that of the pedestal 10, and being arranged such that pairs of ribs
16 outwardly extend from opposite sides of the pedestal with
post-tensioning elements 58 inwardly extending from the distal ends
16x of the ribs 16 through the pedestal 10, [0210] 4. reinforcing
rebar and prestressed dowels 46 extending from the ribs 16 deep
into the core of the pedestal 10 from distal ends 10x, and arrays
of dowels 42, 46, made of rebar, extend between the slab 20 and
each of the ribs 16 and the pedestal 10 along their conjunctions,
[0211] 5. a suitable backfill material 13 placed over the slab 20,
to stabilize the foundation 100 against overturning, followed by
tower base installation and grouting, the foundation 100 is kept
under heavy multi-axial post-compression such that tower loads are
resisted by pairs of ribs 16, on distal ends 10x of the pedestal
10, wherein each pair of ribs 16 form a high stiffness continuous,
non-segmented, laterally supported, post-tensioned girder extending
between distal ends of the foundation 100 with continuous
uninterrupted composite action from the slab-on-grade 20.
[0212] In another embodiment, slab post-tensioning can be arranged
at any combination of perimeter, radial, diametric, or other
patterns.
[0213] In another embodiment, composite action is further
facilitated with radially oriented, reinforcing bars 24r1 locally
arranged in the slab 20, beneath the ribs 16, and extended deep
into the pedestal 10, in addition to an array of vertical dowels 42
extending between the rib and the slab 20 that function as shear
connectors.
[0214] In a preferred embodiment, as shown in FIG. 13, the
invention pertains to a foundation 100 for supporting a wind
generator with a multi-megawatt rating and subjected to extremely
high cyclical upset loads, with increased stiffness and improved
fatigue resistant comprising: [0215] 1. a support slab-on-grade 20
of non-segmented continuous construction with a circular integral
perimeter beam 190 with circumferential post tensioning elements 59
made of two 180-degree tendon segments forming a 360-degree circle,
with anchors 59b at the opposite sides of the foundation, [0216] 2.
a central cylindrical pedestal 10 integral with the support
slab-on-grade 20 of solid non-segmented construction and having
vertical post-tensioning elements, 56 [0217] 3. ribs 16 integral
with the support slab 20 and the central pedestal 10, on top of the
slab 20, with three or four pairs of ribs 16 radially extending
from opposite sides of the pedestal 10 and post tensioning elements
58 extending axially and diagonally from anchors 16an placed at the
distal ends 16x of the ribs 16 through the pedestal 10, such that
the ribs 16 and the perimeter beams 190 function as a prestressed
trussed diaphragm structure with the slab 20 acting as infill
panels, and pairs of ribs 16 on distal ends 10x of the pedestal 10
function as continuous post-tensioned girders, that are free of
construction joints, with continuous composite action from the slab
20 and the foundation 100 is kept under eccentric multi-axial
horizontal and concentric vertical post-compression, with
circumferential post-tensioning 112 in the slab 20 which
effectively reduces stress amplitudes and deflections in the slab
20 by keeping the slab 20 under heavy post-compression in the
direction of the primary slab spans 20s1 which is in a radial
orientation.
[0218] In a preferred embodiment, the rib 16 extends vertically
from the bottom of the foundation 100 to an elevation near the
bottom of the tower base flange 301 to enable the ribs 16 to
participate in resisting bearing loads under the tower base flange
301 by increasing the area of the cross-section involved in bearing
resistance under the tower base flange 301 and increasing the
permissible bearing strength under the base flange 301 or the grout
bed 90a and by increasing the bearing area measured at the
surrounding faces of the concrete. The geometric configuration and
the improvement in bearing resistance, allow concrete with only one
relatively low compressive-strength for the entire foundation
structure. In contrast, high bearing stresses under the tower base
flange 301 in conventional gravity spread footings, requires
concrete with higher compressive strength for the pedestal 10 and a
lower compressive strength for the slab 20.
[0219] The proximity of inner rib ends 16c to the tower base flange
301 allows the inner zones of the ribs 16 to remain under vertical
compression stresses caused by vertical post-tensioning forces
between embedment ring 54 and tower base flange 301. The vertical
compression stress zones in the distal ends of the pedestal 10x
improves the confinement conditions and fatigue resistance in the
rib inner zones 16c.
[0220] Bonded and grouted multi-strand in some applications may be
too expensive and take too long to install as it requires an
additional step of grouting and may not be economical for some
onshore installations. It may then be preferable to use un-bonded,
encapsulated mono-strands, arranged in bundles and installed in the
foundation reinforcing prior to concrete casting, which reduces
construction costs and improves the construction schedule.
[0221] In a preferred embodiment post-tensioning in the foundation
100 is made eccentric, to create cambers in the foundation 100 that
could result in reduced deflections and improved foundation-soil
contact. As an example, the eccentric prestressing of the ribs 16
creates a convex shaped camber in the foundation 100 that helps
reduce the deflections under turbine weight and operating loads.
Similarly cambers can be used in perimeter beams 190 and slab
sections to reduce slab deflections and improve foundation-soil
contact conditions by ensuring a more uniform bearing pressure
under the foundation thus allowing for an optimized foundation
footprint with more uniform pressure over the effective bearing
area.
[0222] The vertical profile (elevation) of circumferential tendons
59 in the foundation 100 may be varied at mid spans and under
supporting ribs 16 to optimize their utilization.
[0223] In another embodiment a gradual transition of geometry at
the conjunction of the structural elements is employed to prevent
stress concentration and fatigue related problems. As an example
the use of fillets and curved transition ft is desirable at the
conjunctions between ribs 16, pedestal 10 and the slab 20.
[0224] In a preferred embodiment, the inner ends of the ribs 16 are
tapered to a wider cross-section as the rib 16 connects to the
pedestal 10, in order to satisfy the high flexural, torsional and
shear demands at the inner zone of the ribs 16, and to distribute
the multi-axial compression over large surface area to help reduce
splitting and bursting reinforcing on the side of the pedestal
10.
[0225] In another embodiment low relaxation post-tensioning strands
are used to reduce post tension losses over time. Concrete
accelerators and plasticizers and other admixtures may be utilized
in the concrete mix design. The small thickness of the structural
elements may allow for on-site steam curing of the concrete.
[0226] A hollow pedestal 10 cross-section may be used, however it
can be problematic. A hollow pedestal above the frost depth where
there is elevated water table may be problematic. In another
embodiment the cross-section of the rib may change and dimensions
along its length may change. For example, the section may start
rectangular and gradually a top flange may be enlarged to reduce
stresses in the upper zone of the rib.
[0227] In another embodiment the pedestal 10 may have an enlarged
cross-section at the top followed by a transition into a smaller
cross-section below. The upper enlarged cross-section may help
improve bearing strength at the top of the pedestal below the tower
base flange 301a, the bearing washer plate 404b, and the high
strength grout bed 90a according to American Concrete Institute
design guidelines.
[0228] The present invention pertains to a foundation design that
overcomes the thermal cracking problem stemming from heat of
hydration, in large foundation pours, by using a structural
configuration coupled with post-tensioning techniques that reduce
the thickness of the structural elements, while increasing the
surface area of the concrete pour, thus improving heat dissipation
conditions and causing a the ratio of concrete mass to surface area
to be roughly 40% to 50% less than in conventional design for
inverted T foundations for the same turbine under the same loading
and geotechnical conditions.
[0229] As shown in FIG. 37, FIG. 38 and FIG. 39, a tower base
leveling and grouting method can be used which does not employ
tower anchor bolts for leveling, or leveling shims which cause
undesirable stress concentration at shim locations which could lead
to localized fatigue failure at shim locations. The new method
employs the bolt template 52 at the very top of the bolt assembly
60 with at least three sets of additional leveling bolts 53 and
corresponding threaded bolt inserts 53b suitable for embedment into
concrete. The leveling bolts 53 and inserts 53b may be located
outside or inside the bolt circle 60a of the tower base, but
directly under the tower base flange 301a. This allows for
continuity of the grout bed 90a construction and provides an easy
access for leveling bolts 53. Small cutouts 53a connected at
leveling bolt locations can be used. Another benefit of this
leveling technique is having the ability to apply a continuous
grout bed 90a that is free of construction joints, under tower base
301 in one session and to have the ability to tension all the
anchor bolts 56 in one session.
[0230] The present invention improves safety and accessibility
around foundations during construction, and reduces hazardous
conditions for construction crews. This goal is achieved by using
reusable form sections 102 that are fitted with platform sections
for forming an access platform around the foundation. The form may
also connect to at least one access ramp extending beyond the edge
of the foundation. The platform and the ramp are fitted with a
slip-resistant walking surface and the elevated ramps are provided
with guardrails and designed to applicable industry safety
standards. Further, the relatively thin slab thickness minimizes
the risk of worker injury during construction.
[0231] A transformer pad can be supported on precast concrete posts
extending vertically from the foundation.
[0232] Pedestal forms 102 may have openings for running electrical
and communication conduits there through thus preventing problems
stemming from randomly placing the conduits in areas that could
compromise the structural design.
[0233] The ribs 16 may have means for receiving and supporting
prefabricated trays (or electrical duct banks) for housing power
and communication cables.
[0234] The foundation design can also be adapted for offshore wind
turbine projects. In this case the foundation 100 may be assembled
on a barge or dry dock then transported or floated to its
destination, and lowered into a prepared seabed location. The
foundation can be weighed down in place by backfilling it with
suitable material. The offshore foundation 100 may be configured to
receive any type of offshore piers 404, suction piers 403, piles
400, micro-piles 401, anchors 404 or any combination of the
above.
[0235] In another embodiment of the invention as shown in FIG. 42,
an offshore concrete foundation 100 with high stiffness and
improved fatigue resistant comprising: [0236] 1. a support
slab-on-grade 20 of non-segmented continuous construction covering
the entire footprint of the foundation and having (horizontal)
diametric and perimeter post-tensioning elements, [0237] 2. a
central pedestal 10 integral with the support slab-on-grade 20 of
solid non-segmented construction and having vertical
post-tensioning elements and also having reinforcing elements of
rebar to carry loads diametrically across the pedestal 10; [0238]
3. a cylindrical or conical stem 11 extending vertically above the
pedestal 10 and being fixed to the pedestal 10, and having a hollow
cross section, of equal size or smaller than that of the pedestal
10, and may be constructed with segmented or non-segmented
construction methods and could be made with typical cast in place
over the pedestal 10 by using typical construction methods for tall
cylindrical concrete structures such as continuous forming,
successive pours, segmental construction with precast concrete
panels or other known construction methods used conventionally for
conical or cylindrical concrete structures such as chimneys, and
the stem 11 is kept under heavy concentric vertical
post-compression stress by an array of circumferentially arranged
vertical post-tensioning elements 70, and the stem 11 may have an
ice cone 11b, or tower receiving adaptor, integral with the top of
stem 11, and the stem 11 having means for fixing a tower base 301
of a wind tower 300, the stem 11 and the ice cone 11b are
vertically and circumferentially prestressed with vertical and
circumferential post tensioning elements, [0239] 4. ribs 16
integral with the support slab 20 and the central pedestal 10, on
top of the slab-on-grade, with pairs of ribs 16 radially extending
from opposite sides of the pedestal 10 with post-tensioning
elements extending radially and diagonally from the distal ends 16x
of the ribs 16 through the pedestal 10 and keeping the ribs 16 and
the pedestal 10 under heavy eccentric post compression stress and
reinforcing dowels 46 extending from the ribs 16 into the pedestal
10 and spliced with pedestal 10 reinforcing, [0240] 5. deep
perimeter beams 190 extending continuously around the foundation,
made of concrete integral with the support slab-on-grade 20 and the
ribs 16 and having continuous perimeter or circumferential post
tensioning elements. When the concrete sets, the post-tensioning
elements are jacked and the anchor bolts are post-tensioned such
that the foundation is kept under heavy multi-axial
post-compression.
[0241] The offshore foundation 100 is constructed on a barge or in
a dry dock and then floated or transported to an offshore
installation site and lowered to be placed over a prepared sea bed.
A suitable backfill material 13 is placed over the foundation 100
to stabilize the foundation against overturning. Scour protection
measures 13b are provided around the foundation. The foundation may
be built with marine cement and marine grout and kept under heavy
multi-axial horizontal and vertical pre-stress using bonded and
grouted post tensioning systems rated for double corrosion
protection and suitable for a marine environment.
[0242] In another embodiment as shown in FIG. 40, an offshore
foundation for wind turbines comprises the following elements:
[0243] 1. A vertically extending pedestal that is cast in situ, on
a barge, out of concrete, the pedestal has an integral long stem 11
for receiving and supporting a tower structure; [0244] 2. A
substantially horizontal support slab 20 that is cast in situ, on a
barge, out of concrete, the support slab 20 covering an area of
ground larger than that covered by the pedestal 10; [0245] 3. A
plurality of radial ribs 16 extending radially outwardly from the
pedestal 10 and spaced around the pedestal 10, each rib being
prefabricated and being joined along the base thereof to the
support slab 20 when the support slab 20 is cast in situ and being
joined along an inner side thereof to the pedestal 10 when the
pedestal 10 is cast in situ; [0246] 4. A plurality of prefabricated
perimeter beams 190 spanning continuously, near the perimeter of
the foundation 100, between ribs 16 and supporting the slab 20;
[0247] 5. Backfill 13 for weighing down the foundation, resisting
tower loads and providing scour protection 13b.
[0248] When the concrete sets, the precast components will become
integral with a cast-in-place components. Radial post-tensioning
tendons extend from the distal end of one rib through the rib and
the pedestal to the distal end of the opposite rib. Vertical
post-tensioning is arranged in the pedestal 10 as well. The stem 11
and the ice cone 11b may also benefit from circumferential
post-tensioning 59t.
[0249] The pedestal 10 has means for receiving and supporting a
tower 300 or pylon. The upper portion of the pedestal 10 (the stem
11) may be made in multiple consecutive cast in situ pours,
depending on its height. Alternatively, the stem 11 may be made by
joining precast segments with circumferential 59t and vertical 70
post-tensioning to form the stem 11 as in segmented concrete tower
construction.
[0250] In another embodiment of the invention, as shown in FIG. 42,
a wind turbine foundation may be fabricated on a barge with precast
concrete elements. The barge surface is prepared with a non bonding
agent or a thin membrane at the foot print where the foundation is
to be built. Lower slab reinforcing mesh sections are assembled and
placed on the barge and the pedestal cage reinforcing is assembled
at the center of the foundation. Upper slab reinforcing mesh
sections 24 may follow after the slab post tension duct 58dc is
placed. Precast concrete ribs 16 are placed in a radial array
around the pedestal cage 50 and precast concrete perimeter beams
190 are arranged around the perimeter of the foundation 100p. Post
tensioning ducts 58dc in the pedestal space 10 and at perimeter
beam-to-rib connections 59dc are placed to pair with their
corresponding duct in the precast members. Forms for the pedestal
10 and for closure pours at rib-to-perimeter beam connections are
installed. The slab concrete is poured followed by pedestal 10
concrete and closure pours at the rib-to-pedestal connections. The
stem 11 is fabricated possibly in multiple consecutive pours
depending on pedestal height. The stem 11 design may incorporate an
ice cone 11b at its top. The post tensioning tendons are then
installed. The jacking and grouting of tendons is then carried out.
Some pylon sections may be installed prior to transportation. The
finished foundation 100 is transported to its offshore installation
site using a suitable means of transportation such as towing the
barge.
[0251] In another embodiment of the offshore foundation comprises
the following elements as shown in FIG. 46: [0252] 1. A vertically
extending pedestal 10 is cast in situ, on a barge or dry dock, out
of concrete; [0253] 2. A substantially horizontal support slab 20
is cast in situ, on a barge or dry dock, out of concrete, the
support slab 20 covering an area larger than that covered by the
pedestal 10; [0254] 3. A plurality of radial ribs 16 extends
radially outwardly from the pedestal 10 and spaced around the
pedestal 10, each rib being prefabricated and being joined along
the base thereof to the support slab when the support slab 20 is
cast in situ and being joined along an inner side thereof to the
pedestal 10 when the pedestal is cast in situ, each rib has an
integral pier 180 for receiving a leg 210 of lattice tower 200;
[0255] 4. A plurality of perimeter beams 190 spanning continuously,
near the perimeter of the foundation 100, between ribs 16 and
supporting the slab 20, optionally each perimeter beam can be
prefabricated; [0256] 5. A lattice tower 200 has a plurality of
legs 210 structurally connected to the integral piers 180 in the
ribs 16, the lattice tower 200 has, at its top, a means for
receiving and structurally supporting a pylon or a tower 300;
[0257] 6. Suitable offshore backfill 13 for weighing down the
foundation, resisting tower loads and providing scour protection
13b.
[0258] When the concrete sets, the pre-cast components will become
integral with the cast-in-place components. Radial post-tensioning
tendons extend from rib ends 16x to the opposite rib ends 16x
across the pedestal 10. Vertical post-tensioning is arranged in the
pedestal 10 as well. The structural behavior is improved by the
added compression in all ribs 16, edge beams 190, slab 20 and
center pedestal 10.
[0259] The lattice tower 200, preferably incorporating
3-dimensional trusses 200tr, transfers the pylon loads down to the
concrete foundation 100. The lattice tower 200 may get connected to
the concrete foundation prior to transportation or it can be
connected to the foundation at final offshore installation
site.
[0260] In another embodiment of the invention as shown in FIG. 46,
a wind turbine foundation is fabricated on a barge with precast
concrete element as following. The barge surface is coated with a
non-bonding agent or covered with a thin membrane at the foot print
where the foundation 100 is to be built. Lower slab reinforcing
mesh sections are assembled and placed in the slab area and the
pedestal cage 50 reinforcing is assembled at the center of the
foundation. Upper slab reinforcing mesh sections may follow after
the slab post tension ducts are placed. Precast concrete ribs 16
are placed in a radial array around the pedestal cage 50 and
precast concrete perimeter beams 190 are arranged around the
perimeter of the foundation 100p. Post tensioning ducts in the
pedestal space and at perimeter beam-to-rib connections are placed
to pair with corresponding duct in the precast members. Forms for
the pedestal and for closure pours at the rib-to-perimeter beam
connections are installed. Slab concrete is poured followed by
pedestal concrete and closure pours at rib-to-pedestal connections.
A lattice tower 200 structure is prefabricated and mounted atop the
concrete foundation 100. The foundation is transported to the
installation site using a suitable means of transportation. The
seabed is prepared for receiving the foundation by placing a
sub-base of suitable material such as crushed stone. The foundation
is backfilled and scour protection measures 13b are installed.
[0261] In another embodiment of the invention, as shown in FIG. 31,
the stem 11 is prefabricated separately and provided with a means
for connecting to the pedestal 10, preferably an array of vertical
post tensioning dowels 70 extended through the pedestal 10 and the
stem 11 or other segmental post tensioning joining methods may be
used. The pedestal may be fitted with a means for receiving the
prefabricated stem 11 based on segmental post tensioning and
grouting construction methods.
[0262] Piles 400, Micro-piles 401 or piers 402 or suction piers 403
or anchors 404 can be used with the offshore foundation 100 in a
similar manner as previously described in the application. In this
case vertical sleeves will be arranged in the foundation to receive
an array of piles 400 or anchors 404 extending through the
foundation, to allow for additional loading capacity and improve
the stability of the foundation. Piles 400 are secured to the
foundation by filling the sleeves with marine grout.
[0263] Under some conditions, the use of piles 400, piers 402 or
suction piers 403 or anchors 404 may eliminate the slab 20 and/or
the perimeter beams 190 from the design.
[0264] In another embodiment shown in FIG. 43 the foundation 100
with perimeter beams 190 has a pedestal 10 which supports a
concrete stem 11 having a steel tower 600 thereon.
[0265] Obviously, many modifications and variations of the present
invention are possible in light of the above teachings. It is
therefore to be understood that, within the scope of the
invention.
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