The invention relates to a pre-stressed concrete structure.
In a pre-stressed concrete structure such as a concrete wall or a concrete beam a steel strand is tensioned and concrete is poured directly around the strand for curing, allowing bonding of the concrete with the strand.
Once cured, the steel strand tension is released resulting in compression of the concrete structure. The bond strength of the strand to concrete keeps the compression intact.
The prior art knows such pre-stressed concrete structures with uncoated steel strands.
Concrete is an alkaline environment and in quite some applications, there is no problem with the life time and corrosion of the reinforcing steel strands. However, in other more demanding applications, e.g. in marine environments, there is a huge demand to increase the life time of pre-stressed concrete structures, and, as a consequence the life time of the reinforcing steel strands.
Using galvanized steel strands did not result in reaching the same bond strengths as with uncoated steel strands, on the contrary, the bond strength of galvanized steel strands to cement or concrete was lower than with uncoated steel strands.
It is a general object of the invention to mitigate the drawbacks of the prior art.
It is a particular object of the invention to obtain pre-stressed concrete structures with a longer life time.
It is another object of the invention to increase the bond strength of steel strands to cement or concrete.
It is yet another object of the invention to increase the corrosion resistance of steel strands in pre-stressed concrete without deteriorating the bond strength of these steel strands in concrete.
According to the present invention there is provided a pre-stressed concrete structure comprising a steel strand or a steel wire. The steel strand or steel wire has been pre-tensioned before curing of the concrete or grout. The steel wire or the steel strand is provided with a zinc coating. The zinc coating has a weight ranging between 70 g/m2 and 950 g/m2. The steel wire or the steel strand has an outer surface that is provided with indentions to provide mechanical anchorage points in the concrete structure. In addition, the steel wire or the steel strand is provided with a passivation layer in the form of a metal oxide layer.
Within the context of the present invention, the terms “zinc coating” refer not only to a pure zinc coating but also to zinc alloy coatings, such as zinc aluminium alloy coatings and zinc aluminium magnesium alloy coatings.
The reason why uncoated steel strands have a better bond to the concrete than zinc coated steel strands, if no additional measures are taken, is due to the hydrogen evolution during the initial stages of curing of the concrete. The reaction of zinc in high pH wet concrete creates hydrogen gas, which leads to bubbles in the interface of steel with concrete which may lead to voids between the concrete and the steel strands. These voids reduce the friction resistance between the steel strand and the concrete and thus the bond strength between the steel strand and the concrete.
The above-mentioned indentions are now intended to bridge the voids and to restore the bond strength. The metal oxide layer is intended to modulate the reaction gases between the zinc and high pH concrete water to reduce the occurance of aforementioned voids. The combination effects of indentions and metal oxide layer is to increase the friction between the zinc coated strands and concrete.
Preferably, the steel wire or the steel strand has a yield strength that is more than or equal to 85%, e.g. more than or equal to 90% per cent of the minimum guaranteed tensile strength. The advantage hereof is to reduce long term construction creep and maximize working capacity of the steel strands and the concrete structure.
The metal oxide layer on the surface of the galvanized steel strand or steel wire is an oxide layer selected from the group of zinc oxides, chromium oxides, zirconium oxides, aluminium oxides, titanium oxides or combinations thereof.
The reinforcing steel element can be single steel wire, or three steel wire strand (3×1) or a seven steel wire strand in a 1+6 construction, i.e. with one core wire and six wires in the mantle around the core.
The steel wires, either used singularly or as twisted multiple wires in a strand, may have a diameter ranging from 2.9 mm to 8.1 mm, e.g. from 3.0 mm to 7.0 mm.
The indentions may have a depth ranging from 0.05 mm to 0.20 mm, e.g. from 0.06 mm to 0.18 mm.
A galvanized steel reinforcement for a pre-stressed concrete structure is made along following lines.
A wire rod with a diameter ranging from 8 mm to 15 mm and a steel composition with a carbon content ranging from 0.70% to 0.95%, a silicon content ranging from 0.30% to 1.3%, a manganese content ranging from 0.30% to 0.80%, a sulphur content being below 0.025%, a phosphorous content being below 0.025%, the rest being iron and unavoidable impurities forms the starting product, all percentages being percentages by weight.
The wire rod is cold dry drawn until a wire is obtained with a final diameter between 3.0 mm and 7.0 mm.
The steel wire is then conducted to a hot dip galvanizing bath to provide the steel wire with a zinc coating ranging from 70 g/m2 to 950 g/m2, e.g. from 80 g/m2 to 800 g/m2. The wire may be used as “end galvanized” or “redrawn” with the zinc coating. The wires can then be indented in the final zinc surface to the specifications outlined in
In case of a steel strand several wires, e.g. three steel wires or seven steel wires, are twisted into a steel strand, e.g. a 1×3 steel strand or a 1+6 steel strand.
The steel wire or the steel strand is then subjected to a relaxation process. More particularly, the steel wire or steel strand is heated under tension in order to obtain high yield strength.
After relaxation, mechanical indention is applied to the steel wire or steel strand. In the case of a steel strand this mechanical indention can also be applied on the individual steel wires before the twisting operation.
Finally, a passivation chemical is applied to the indented steel wire or steel strand to create a metal oxide on the surface. This metal oxide may reduce the hydrogen evolution during the initial stage of the curing process and may provide sufficient friction between the steel wire or steel strand and the concrete.
During the pouring of the concrete around the steel wire or steel strand, the steel wire or steel strand are kept under a tensile tension. After curing the tension is then released in order to put the concrete structure under compression.
Steel strand 20 of
Steel strand 30 or
Steel strand 36 of
Four different 1+6 galvanized steel strands with a diameter of 15.24 mm (0.6 inch) have been evaluated regarding their bond strength according to the ASTM A1081-15 test method for evaluating bond of a seven wire steel pre-stressing strand. The difference between the strands was the number of indented layer wires:
the 1st strand had no layer wires with indentions;
the 2nd strand had one layer wire with indentions;
the 3rd strand had three of the six layer wires with indentions, one layer wire with indentions alternating with a layer wire without indentions;
the 4th strand had all six layer wires with indentions.
There were 24 specimens, six cast with each of the four strand types. Mortar flow was measured in accordance with the procedures specified in ASTM Test Method C1437 and was determined to be 112%.
Table 1 below lists the average pullout test results for each of the four strand types.
In order to determine the decrease in beam transfer length growth, four pre-tensioned concrete beams were made:
two with a galvanized 1+6 strand without indentions;
two with a galvanized 1+6 strand with indentions provided on all the six layer wires.
The strands were initially tensioned at 75% of the minimum breaking strength. Tensioning was performed using mechanical gear jacks that were coupled to load cells. Concrete was cast and de-tensioning of the strands occurred over a period of couple of minutes once the concrete had reached a compressive strength of 38 MPa. End-slip values were obtained by measuring the distance that each strand slipped into the beam at the ends. Initial position was determined just after de-tensioning and the final position was determined 15 days after de-tensioning. The mast strand slip theory by Logan was determined to calculate the transfer length values.
The galvanized 1+6 strand without indentions showed an average increase of transfer length of 14.6%, whereas the galvanized 1+6 strand with six layer wires indented showed only an average increase of transfer length of 2.7%, which is a significant decrease.
The above-mentioned results on bond strength and on decrease in transfer length of the galvanized indented strands are at least equally good as results obtained from comparable non-galvanized strands.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/063953 | 5/28/2018 | WO | 00 |
Number | Date | Country | |
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62526430 | Jun 2017 | US |