The present invention relates generally to anchorage systems and, in particular, to ground anchorage systems suitable for underground structures and above ground structures. It should be understood however that the invention is intended for broader application and use.
Ground anchors are an integral construction technique for numerous civil engineering applications ranging from deep excavation support to resistance of structural uplift and overturning of superstructures. Ground anchorage systems can be designed to be temporary, such as for use in temporary wall support in deep excavations. They can also be designed to be permanent for use in structures, for example, bridges and dams.
There are two significant types of anchorage systems which are in use; wedge type systems and bond type systems. Essentially, a wedge type anchorage system consists of steel wedges to grip single or multiple tendons in a tube with an inner conical profile and an outer cylindrical surface. Bond type anchorage systems on the other hand consist of a steel housing inside which single or multiple tendons are bonded by filling grout.
As used herein, a tendon is an elongate member adapted to be placed under load in an anchorage system. A tendon may consist of a single wire or strand, but more usually consists of a plurality of strands held together, for example by being helically wound.
A current wedge type anchorage system 130 is shown in
In the case of a tendon formed from composite material, this compressive action of the wedges onto the tendon induced by the housing of the wedges into the anchor block, produces high concentrations of lateral stresses, causing premature fibre rupture of the tendon.
Present anchorage systems using steel tendons have the disadvantage that they are susceptible to corrosion and, as such, anchorage system standards require the use of double corrosion protection systems encapsulating the steel strands, to ensure a serviceable design life.
Most FRP anchorage systems alter the physical properties of the tendons being used, this is disadvantageous because altering of the properties may cause corrosion of the tendons and they may not perform as expected. Furthermore, in the case of bond type systems, the bond length required can be substantial, making it very difficult to work in areas where space is a premium. In addition, because a lot of material is required for the long bond length, costs are increased.
It is therefore desirable to provide an anchorage system which is less susceptible to corrosion with a minimal bond length.
Discussion or mention of any piece of prior art in this specification is not to be taken as an admission that the prior art is part of the common general knowledge of the skilled addressee of the specification in Australia or any other country.
According to one aspect of the present invention there is provided an anchorage system including a composite tendon comprising an assembly of elongate elements held together. The anchorage system also includes an anchor head including a casing. The individual elongate elements are separated from each other at one end, the separate elements extending into the anchor head; The anchor head casing is filled with an adhesive medium to secure the separated elements in the casing.
Preferably the assembly of elongate elements includes a primary wire and a plurality of secondary wires wound around the primary wire.
The anchor head in the anchorage system may further include an anchor plate adapted to be secured to a bearing plate.
In the anchorage system the primary and/or secondary wires are preferably made of fibre reinforced polymer (FRP), and more preferably carbon fibre reinforced polymer (CFRP). Alternatively the wires may be made of aramid fibre reinforced polymer (AFRP) or glass fibre reinforced polymer (GFRP).
The adhesive medium in the anchor head casing is preferably made of cementitious grout. The grout may be made from normal strength cementitious grout, high strength grout mixtures, expansive grout mixtures or concrete. Alternatively the adhesive medium may be resin based grout, such as, polyester resin, vinyl ester resin and epoxy resin.
The anchor head and the bearing plate are preferably made of metal, such as, mild steel, high strength steel, carbon steel, stainless steel or galvanised steel.
Alternatively the anchor head and/or bearing plate may be made of non-metal based materials, including plastics, resins, ceramics, fibrous products and polymers.
According to another aspect of the present invention there is provided a method for installing an anchorage system including the steps of:
inserting in a borehole at least one composite tendon comprising an assembly of elongate elements held together;
separating the individual elongate elements from each other over a pre-determined anchor head length;
placing an anchor head casing around the separated elements; and
filling the anchor head casing with an adhesive medium, thereby once the adhesive medium has set, the separated elements are securely fixed into the anchor head.
Preferably the composite tendon comprising an assembly of elongate elements held together includes a primary wire and a plurality of secondary wires wound around the primary wire. The secondary wires are preferably unwound from the primary wire of the composite tendon to separate the individual elongate elements from each other
The cables may be manually unwound in situ. Alternatively, the cable may be supplied with the secondary wires unwound from the primary wire at one end of the cable.
Preferred embodiments of the present invention will now be described with reference to the accompanying drawings. These embodiments are given by way of illustration only and other embodiments of the invention are possible. Consequently, the particularity of the accompanying drawings is not to be understood as superseding the generality of the preceding description.
In the drawings:
Embodiments of the anchorage system will now be described with reference to the accompanying drawings.
In general, the present invention relates to an anchorage system including a composite tendon comprising an assembly of elongate elements held together. It also includes an anchor head including a casing. The individual elongate elements are separated from each other at one end, the separate elements extending into the anchor head. The anchor head casing is filled with an adhesive medium to secure the separated elements in the casing.
The anchor head casing 6 as shown in
The primary 4 and/or secondary 5 wires are preferably made of fibre reinforced polymer (FRP). More preferably they are made of carbon fibre reinforced polymer (CFRP). Alternatively they may be made of aramid fibre reinforced polymer (AFRP) or glass fibre reinforced polymer (GFRP).
In FRP materials a polymeric matrix is used to bond the fibres, protect the fibres against environmental effects and assist in the equalisation of fibre forces and load transfers in the transverse direction. Thermoplastic and thermoset polymers can be applied with FRP fibre filaments to form an FRP composite material. Thermoset polymers including epoxy, polyester and vinyl ester are preferred resins for FRP material selection in permanent ground anchor applications.
In a preferred embodiment, the anchorage system 1, as shown in
Once the wires are unwound over the pre-determined bonded anchor head length 22, an anchor head casing 6 is placed around the outside of the unwound wires 4, 5. The tendons 2 extend through the anchor bearing plate 12. It is undesirable to have a long anchor head bond length. The present invention enables the anchor head bond length to be kept to a minimum.
The anchor head casing 6 is not limited to metal; non-metal materials can be used for this casing. However, preferably the anchor head casing is made of metal, which may include mild steel, high strength steel, carbon steel, stainless steel or galvanised steel. Alternatively, if the anchor head casing is made of non-metal based materials, plastics, resins, ceramics, fibrous products and polymers can be used.
The anchor head casing 6 may then be secured to a bearing plate 12 and then filled with an adhesive medium 10. The adhesive medium can be cementitious (grout based) or synthetic (resin or epoxy based). Preferably the adhesive medium is made of cementitious grout. This may include standard strength grout mixtures, high strength grout mixtures, expansive grout mixtures or concrete. Alternatively the adhesive medium may be resin based grout including polyester resin, vinyl ester resin or epoxy resin.
Once the adhesive medium 10 has set, the unwound wires 4, 5 are securely fixed into the anchor head. This process of unwinding the FRP wires and fixing them with grout increases the total surface area between the FRP wires and the surrounding adhesive medium. This increases the total frictional area used to resist applied forces through from the stressing of the ground anchor. Where the wires are fixed to the surrounding adhesive medium 10 forms an area whereby the ground anchor can then be stressed and locked off, holding the required engineered loads for its application, for example a bridge, dam or car park.
This system utilises bond forces generated between the extended surface area of the unwound FRP wires and adhesive material, and between the adhesive material and the surrounding anchor head casing. No mechanical interlocking between the FRP wire and the adhesive material or anchor head casing is used to establish load lock off.
In addition, the tendons 2 may be manually unwound. The unwinding process does not interfere or alter the properties of the wires. This is due to the tendon or wires not being physically changed, for example, by cutting. Only their physical configuration is altered; each wire is intact, but separated from the other wires.
Since the bonding surface area is increased, thus the anchorage system is able to support a larger force than conventional anchorage systems. The anchorage system is able to reduce the required anchor head bond length to successfully support the ultimate tensile capacity of the anchor system. Current FRP guidelines (ACI440.3R-04: Guide Test Methods for Fibre-Reinforced Polymers (FRPs) for Reinforcing or Strengthening Concrete Structures) recommend a much longer bond length for various FRP materials, but by using the present invention, the bond length can be significantly reduced.
This reduction in required anchor bond length has substantial benefits including system approval for works in areas where completed surface space is a premium, material cost, labour cost, easier manhandling both during fabrication and onsite. The anchorage system described above enables the preconstruction of the anchor head system prior to installation, thus fabrication and quality control can be more easily monitored.
By way of illustration,
As shown in
The FRP tendon of
The bearing plate 12 is preferably (like the anchor head) made of metal. Alternatively, it may be made of non-metal based materials.
Unlike many other anchorage systems, the present invention does not use a tapered wedge system to lock each wire into place once a load is applied. In this anchorage system, all the unravelled secondary wires are grouted in one medium. As such, the unravelled wires within the pre-determined bonded length 22 effectively act as one uniformly tensioned system during the stressing phase.
Stressing of bond type anchor head system can be conducted as per conventional anchor stressing procedures. Hydraulic jacks can be placed under the anchor head system 1 and are used to place an applied load (of known amount) into the anchor tendon. Once the system has reached its design lock-off load shims are used to lock the anchor head system into place. Once the shims are in place, jacks are removed and the anchor is classified as stressed.
Results from a series of tests to verify advantageous properties of an anchor head system according to the invention are shown in the graphs of
As the present invention may be embodied in several forms without departing from the essential characteristics of the invention, it should be understood that the above described embodiment should not be considered to limit the present invention but rather should be construed broadly. Various modifications and equivalent arrangements are intended to be included within the spirit and scope of the invention.
Number | Date | Country | Kind |
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2009906252 | Dec 2009 | AU | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/AU2010/001724 | 12/23/2010 | WO | 00 | 8/7/2012 |