EP1315867A1 - Method for tensioning multiple-strand cables - Google Patents

Abstract

The invention concerns a method whereby the strands (13, 13A) are fixed one after another between two cable anchors (A, B) integral with the structure. The method consists: in pulling on one of the ends of a strand (13A) from one (A) of the cable anchors, while the other end is fixed on the other cable anchor (B); continuously testing the tensioning condition of the strand (13A), said condition involving in particular the measured values of the strand tension and of a predetermined parameter. The invention is characterised in that the predetermined parameter is the variation of the distance separating the cable anchors (A, B).

Description

 The present invention relates to a method of tensioning a multi-strand guy.

Multi-strand stays can be used in all kinds of civil engineering works, in particular to support long-span structural elements (bridge decks, stadium covers) or to ensure the stability of slender structures (microwave towers, for example ).

Anyway, in these types of civil engineering works, the strands of a shroud should be tensioned: a) so that, on the one hand, the total tension force of a shroud is distributed uniformly between all the constituent strands, and this to avoid any dangerous overvoltage of some of them, leading in particular to risks of rupture by fatigue, b) but also, so that, on the other hand , the shroud, considered as a whole, is adjusted to a level as close as possible to the theoretical level provided during the design of the structure.

FR 2 652 866 describes a method of tensioning a guy strand with multiple strands, making it possible to ensure a uniform distribution of the tension between all of the strands (point a, above). In this process, we start by setting up and tensioning the first strand, known as the control strand, which we then anchor by providing it with a measuring cell, which will allow us to know the tension force in this control strand at any time. instant of the stay cable installation operation. Then we place and gradually tighten a second strand that we anchor at the precise moment when we obtain equality between its tension and that which then prevails in the control strand. We proceed in the same way for the third strand: we introduce it into the stay, then we gradually tighten it until its tension and that of the control strand become identical. And so on until the last strand is tensioned and anchored. Then the control strand is relaxed, the measuring cell is dismantled and again stretched to the voltage value last measured by the cell. Consequently, each time a new strand is introduced into the stay, its tension is set to that of the control strand; the two tensions, identical at the time of anchoring of this new strand, remain equal, subsequently varying in the same way when the relative position of the anchors changes: a) either, under the effect of the progressive increase in the shroud tension as the strands are put in place, b) either, under the effect of an external load applied to the structure. This process, known as the iso-tension process, therefore makes it possible to set up all of the strands of a shroud, guaranteeing a priori a uniform distribution of the total force of the shroud between all the strands. However, it has several drawbacks. First of all, the equality of the tensions of the new strand and of the control strand continues to be satisfied over time only if the two strands were at the same temperature when the new strand was anchored. Experience shows that this is not always the case: the control strand contained in a sheath exposed to the sun can have a temperature a few tens of degrees higher than that of the new strand being laid. After standardization of the temperatures, there is then a dispersion between the values of the voltages of each strand which can exceed 10%. Hence, sometimes the need for a retensioning operation, using the process described, to standardize the values of the strand tensions, and consequently additional work. In addition, if the known method makes it possible to impose an identical tension on all the strands at the time of the installation of the shroud, the problem of adjusting a shroud in accordance with the specifications imposed by the design studies of the structure remains, it , outside the scope of this known process.

One conceivable approach could consist in calculating, from the stiffness characteristics of the structure on which the stay is fixed, the tension to be applied to the first strand, so that the stay reaches, at the end of the operation of placing the strands, a given total tensile force. However, experience shows that this procedure lacks precision, taking into account the uncertainties affecting the actual loading of the first strand such as the real conditions of contact of the sheath, the presence of end tubes temporarily supported by the strand, and others. In practice, this difficulty is overcome by proceeding in two stages: firstly, the strands are put in place as indicated above to reach a fraction of the final tension (from 60 to 90%, depending on the projects), - in a second step, the elongation to be imposed on all the strands is evaluated by appropriate means in order to reach the final level of adjustment, this calculation giving reliable results, since it is reasonable to estimate that the weight of the sheath is uniformly distributed among all the strands; the computed value of the elongation is then generally imposed on the control strand, the other strands then being tensioned using the iso-tension process.

It is obvious that this double process greatly complicates the work, and therefore the cost, associated with the operation of fitting and adjusting a stay cable. In addition, the known method requires, at the end of work, the relaxation of the tension of the control strand, the disassembly of the measurement cell and the re-tensioning of this strand to the previously measured voltage value; this also complicates the work.

The object of the invention is to provide a method for tensioning a multi-stranded stay which is free from the drawbacks of the prior art.

The subject of the invention is therefore a method of tensioning a strand with multiple strands in which said strands are placed one after the other, between two anchorages integral with the structure, the method consisting in: pulling one end of a strand from one of the anchors, while the other end is fixed to the other anchor, to measure continuously, the value of the tension in the strand, and to test so continues an end of tensioning condition, this condition bringing into play an expression as a function of a predetermined parameter, characterized in that said predetermined parameter is the variation of the distance separating said anchors.

Thanks to these characteristics, it becomes possible: to ensure a uniform distribution of the total tension of the shroud between all the strands, even if these are at different temperatures during laying, to impose on the shroud, considered in as a whole, a level of adjustment as close as possible to that specified during the design of the structure, even if the actual loading conditions of the structure differ from those taken into account in the calculations for the phase considered, to remove the intermediate strand retensioning steps required by the prior art. According to other advantageous characteristics of the invention, the method also consists in: a) determining the theoretical value of the length at zero tension of the shroud, as a function of: the total number of strands of the shroud, the axial stiffness and the weight line length of each of the strands of the shroud, of the theoretical position of the anchors as defined by the plans of the structure, of the values of the tension of the shroud and of the displacements of the anchors provided for by the calculations of the design of the structure for a phase of predetermined reference located after the tensioning operation of the stay cable, b) to evaluate the initial displacements of the anchorages as they occur just before the laying of the first strand of the stay cable, c) during the tensioning of each strand of the shroud: to continuously measure said variation in distance counted from step b), to implement a calculation loop to continuously test the condition of end of setting in tension of the strand, using said expression as a function of said predetermined parameter, and d) blocking the strand during tensioning on the anchor as soon as the condition of end of tensioning of the strand is satisfied.

The method according to the invention can be carried out essentially according to two modes of implementation.

Thus, according to a first mode of implementation: said expression as a function of said predetermined parameter defines the remaining elongation to be applied to the strand until the condition of end of tensioning is satisfied.

In this case, said expression can be defined by the following parameters: i) the stiffness and the linear weight of the strand, ii) the theoretical value of said length at zero tension, iii) said initial displacements, iiii the tension measured in the strand , and iiiii) said variation in distance, and the strand is locked, when the value of the elongation remaining to be applied becomes equal to zero.

It may then be preferable for said expression to also be defined by a value representing the return of the keys by which said strand is anchored on its anchorage.

According to the second embodiment, said expression as a function of said predetermined parameter can define the blocking tension which said strand must reach before it can be anchored.

In this case, said expression is defined by the following parameters: i) the stiffness and the linear weight of the strand, ii) the theoretical value of said length at zero tension, iii) said initial displacements, and iiii) said variation in distance, and the strand is locked when the measured value of the voltage applied to said strand becomes equal to that of the tension thus calculated. According to other characteristics of the process applying to the two modes of implementation as defined above: said initial displacements are measured on the structure according to a procedure taking into account the tolerances of realization of said structure or from the results design calculations for the structure; the shroud comprising a protective sheath, the method also consists in: i) determining the theoretical value of said length at zero voltage from the linear weight of said sheath, and - ii) during the calculation relating to said condition of end of placing in tension, to increase the linear weight of the strand during tensioning by a fraction of the linear weight of the sheath; the method also consists in the course of step c) taking into account, in the calculation relating to said condition of end of tensioning, the temperature of the strand in the course of tensioning, the method also consists in 'step b) to take into account in the determination of said initial displacements, the temperatures of the shrouds already installed on the structure and of the structure itself.

Other characteristics and advantages of the present invention will become apparent during the description which follows, given solely by way of example and made with reference to the appended drawings in which: FIG. 1 is an explanatory diagram with the aid of which are defined several concepts used during the execution of the tensioning process according to the invention; - Figure 2 is a very simplified representation of an installation for the tensioning of a stay; FIG. 3 is a flowchart illustrating the steps of calculation of a first mode of implementation of the method according to the invention; FIG. 4 represents a flowchart illustrating the steps of calculation of a second mode of implementation of the method according to the invention; and FIG. 5 represents a variant of an apparatus for measuring the variation in distance between anchorages of a stay cable usable with the method according to the invention.

The description which follows of the preferred mode of implementation of the method according to the invention relates, as a structure on which guy lines are to be installed, to a guyed bridge whose supported deck is constructed by successive cantilevers, case in which the implementation of the process is particularly profitable. However, it is expressly specified that this process is not limited to this particular case, any work involving the installation and tensioning of guy wires with multiple strands which may constitute a case of application of the method according to the invention.

In the diagram of FIG. 1, we consider, in profile view, a symmetrical cable-stayed bridge comprising two pylons 1 and 2 and an apron 3 which rests on piers 4 in line with the lateral spans 5 and 6. It is assumed that in the central span, that is to say between the two pylons, this deck 3 is constructed by successive cantilevers, the lateral spans 5 and 6 being able either to be carried out parallel to the construction of the central span with the same technique, or have been built previously using another method (construction on a hanger, pushing). Anyway, we are interested in the context of the examples described, and without detracting from the generality of the invention, in the tensioning of a shroud in central span, all of the shrouds anchored on a pylon being installed almost symmetrically, in order to guarantee its stability. Some shrouds are represented in 7, 8, 9, 10 and 11.

Part 3A of the central span is deformed under the effect of its own weight and the action of the shrouds which support it, as well as under the effect of possible site loads (mobile equipment, equipment, handling equipment, etc.). ..). Of course, in FIG. 1, this deformation is very greatly exaggerated.

It is also assumed that in the next construction phase of the structure, a new guy 12 (not shown in Figure 1) will be installed next to the guy 8 and tensioned using the method according to the invention.

The following description of the tensioning process refers to the concept of "displacement" used by specialists in the field concerned. In this context, the "displacement" of a point M of a structure being in a given state is equal to a vector PoP, P ₀ designating the position of point M for a state of the structure deemed to be origin state, and P being the position of point M for the given state considered.

Within the framework of the calculation of the expressions intervening in the condition of end of tensioning of a strand according to the invention, any convention relating to the definition of the origin of displacements of an anchoring can be adopted, this definition of origin, once chosen then being applied throughout the calculation process. The following description of the process also calls upon the concept of

"length at zero tension" of a stay or of a strand, a concept which makes it possible to characterize theoretically the level of adjustment of a stay in place. The zero-tension length L of an installed strand is, by definition, the length that this strand would present, if it were to be cut in line with its anchors and if it was measured by keeping it rectilinear with negligible tension. It is because the zero tension length L of a stay cable is smaller than the straight distance d between its anchors, that this stay cable can develop a tension T, of vertical component V balancing the weight of the section of the deck corresponding. By a judicious choice of the value of the length at zero tension of each of the shrouds of a structure, the structure is adjusted so that the stresses which it undergoes during construction as in service remain admissible, even if it means proceeding resumption of adjustment at certain stages of construction. As already indicated, the strand is adjusted by pulling on its end located on the side of the active anchor A using a jack 15 (see FIG. 2): any elongation Δl imposed by the jack on the strand produces a corresponding decrease Δl in the zero voltage length L of the latter.

With regard to the described examples of implementation of the method of the invention, certain basic concepts are illustrated in FIG. 1. The expression “profile (0) in dashed line” means the profile of the structure from which displacements are measured; the profile (R _pr ) in solid lines, the profile associated with a predetermined phase chosen as a reference. The reference state is used to define the level of adjustment that the guy must have at the end of the tensioning operation. No attempt is made at this stage to obtain a given tension force, a value which would then be dependent on site loads, the intensity and position of which cannot be predicted with precision in advance. On the contrary, the computer calculation implemented aims to impose an adjustment of the shroud, such that if in the reference state the anchors of this shroud actually exhibit the displacements predicted by the design calculation, then the tension of the shroud in said state reference is also that provided by the design calculation. It is important to note that the values relating to the reference state of the tension of the shroud and of the displacements of the anchorages taken into account in the adjustment calculation, are the theoretical values directly resulting from the design calculation, and that they then constitute in a way, the adjustment specifications imposed by the design studies for on-site production; the profile (I) in solid line associated with the phase of measurement of the initial displacements of the anchors;

UApr \ displacement of the lower anchor A of the shroud considered in the predetermined reference phase;

ÏJAi: initial displacement of anchor A; _. : vector position OAo of the anchor A from which the displacements are measured, 0 designating the origin of the Oxyz coordinate system in which the work is described.

Of course, analogous vectors are assigned to the top anchor B of the shroud considered, namely m _P r, Î7BI and XB.

We will now refer to Figure 2 which shows in profile the guy 12 in progress installation between its two anchors A and B, respectively on the deck part 3A and the pylon 1. The structure of these anchors can be that described in the aforementioned French patent. The anchor A is assumed to be that in which the jaws or anchor keys are present by means of which the deemed active end of each strand is made integral with the anchor. The top anchor B is assumed to be "passive.

The shroud 12, and all the other shrouds already in place or yet to be installed, comprise a plurality of strands 13, the number of which varies widely in practice, to fix ideas, between 30 and 80, their length being able to reach 250 meters or more . In addition, in the embodiment described, each guy comprises a protective sheath 14 enveloping all the strands 13. This sheath 14 is disposed between the anchors A and B without being fixed to it, at the same time that is put in place the strand which will be tensioned first for the shroud considered. The sheath will therefore be threaded onto this first strand and all the other strands of the same shroud will then be threaded into the sheath before being anchored. However, in certain works, it is possible to dispense with a sheath around the strands provided that these are sufficiently individually protected against the risks of corrosion.

In Figure 2, four strands 13 are already in place and tensioned and a fifth strand 13A has been threaded into the sheath 14 and anchored on the top anchor B. It is therefore being tensioned.

To this end, a tensioning jack 15 known per se is temporarily mounted on this strand 13A. It is associated with a sensor 15A measuring the traction force which it exerts on the strand 13A.

The device for implementing the method according to the invention comprises, in addition to the actuator 15, a microcomputer 16 on which are stored in a permanent memory 17, in the form of files, all the data relating to the shrouds to be put in place on the book.

According to the invention, this microcomputer 16 is connected to the sensor 15A of the actuator 15, and also to means for measuring the distance between the anchors A and B in order to take note of the variation in distance between them during the setting. in tension of each strand 13, 13A. In the case shown, these measurement means comprise a laser rangefinder 18 fixed to the structure of the structure near the anchor A and a reflector 19 intended to return the measurement laser beam emitted by the rangefinder 18. Such rangefinders are well known to specialists. The microcomputer 16 is also connected to a temperature sensor 20 intended to read the temperature of the strand during tensioning. Similarly, the microcomputer 16 is connected to another sensor 22 which measures the temperature prevailing at the interior of a control stay section 21. This control section, composed of a bundle of strands and a sheath element enveloping them, is suspended or otherwise arranged above the deck part 3A in the vicinity of the shrouds already installed. It then makes it possible to apprehend the value of the temperature prevailing in the sheath of the shrouds already installed without having to drill the sheath of the latter to introduce a sensor there.

Referring now to FIG. 3, we will describe the calculation algorithm used by the microcomputer 16 to execute the first mode of implementation of the method of the invention, using the data provided to it. by the voltage sensor 15A, the permanent memory 17, the rangefinder 18, and the temperature sensor 20. It is assumed that, by an appropriate topographic procedure, it was possible to measure on site the actual values of the displacements of the anchors ÏÏAJ and ÏÏBI, just before laying the first strand. If this is not the case, we can always rely on the theoretical values of these displacements provided for in the design study for this phase, provided however that the planned loading is strictly observed on site and carried out by computer the correction of these values, made necessary because the temperatures of the structure and the shrouds already in place generally differ from the theoretical values taken into account at the time of the design calculation (hence the interest in this case of the temperature sensor 22 ). In the context of this first example of implementation, it will be admitted that the condition for the end of the tensioning of the strand taken into account is expressed by taking the elongation Δl remaining to be applied to the strand as a control parameter: pull on the active end of the strand when the value of this elongation becomes zero.

However, another example of implementation will be described later in which the voltage indicated by the sensor 15A will be adopted as a control parameter; in this case, the end of tensioning of the strand condition is reached when the tension in the strand during laying reaches a certain value, called blocking, calculated by the microcomputer 16 according to the measurements carried out and the data stored .

It will be noted however that the first example of implementation has the advantage of being able to directly take into account in the adjustment procedure the systematic effect of recoil presented by certain anchoring devices when the tensioning cylinder is released. 15, and commonly known by specialists under the name of "re-entry of keys".

Whatever the method chosen, however, at the end of the design studies, we have the data necessary to calculate the theoretical value of the zero voltage length L _t of each guy to be installed. This calculation is made on the basis of the following data (see step SI of FIGS. 3 and 4): the theoretical positions -_ and XB of the anchorages A and B from which the displacements are measured, the theoretical values, resulting from design calculations, of the tension T _pr of the shroud and the displacements -Z and TIB „, of its anchorages A and B for the predetermined reference phase, the axial stiffness EA of the shroud, obtained as the product of the number of strands n constituting the shroud, by the apparent elastic modulus E of a strand and by the section a of a strand : EA = nEa the linear weight q of the shroud, given by q = q _g + nq _t , q _g representing the linear weight of the sheath 14 and q _t the linear weight of a strand.

To calculate the value of Lt _h , we are led to solve the following problem of Applied Mechanics: "Given on the one hand two points A and B of space whose relative position is characterized by the vector AB = AB _P = xBo + iïBj ,,) - xAo-rï7Ap,), given on the other hand a cable of axial rigidity EA and linear weight q, determine the length L of this untensioned cable so that, once anchored in A and B , it exerts on point A a force equal to a given value T _A ". The classical theoretical model of the Elastic Chain makes it possible to establish the equations necessary for the resolution of this problem. A presentation of this model is given in particular in the work "Cable Structures" by H. Max Irvine published in 1981 by The MIT Press Séries in Structural Mechanics, pages 16 to 20. Symbolically, the theoretical value L _tn of the length of the stay at zero tension appears as a function of EA, q, ABpr, and T _pr :

In the two examples of implementation, the method of tensioning a stay cable begins with the determination of the values __ and ÛBI of the reputed initial displacements of the anchorages (Step S2 of Figures 3 and 4). These values can be obtained essentially in two ways: either, they are measured on the structure by methods known per se of geometric monitoring of the pylon 1 and the deck 3A; or they are estimated from the corresponding theoretical values, which will have been extracted from the design calculations and stored in permanent memory 17.

In the second case, an actual load must be imposed on the structure as close as possible to that taken into account in the design calculations, in particular with regard to site loads (equipment, lifting equipment, etc.) .In addition, in this case, a correction of the raw theoretical values will have to be made to take account of the fact that neither the guys already installed nor the rest of the structure are at the uniform construction temperature taken into account in the design calculations. This corrective calculation is carried out by reading, via the sensor 22, a value representative of the temperature of all the guy lines installed and by entering an average value of the temperature of the rest of the structure; the computer 16 then performs the necessary calculations based on cases of unit thermal loads determined during the design studies and stored in the permanent memory 17.

In what follows, we will only study this first case by applying it in the two examples of implementation described. Once the initial displacements of the anchors have been determined during step S2, the threading and the actual adjustment of each of the strands of the shroud are carried out.

The following operations of the method according to the invention are carried out each time a strand 13 is tensioned. In accordance with the first example of implementation illustrated in FIG. 3, during this tensioning operation (for example of the strand 13A), the computer 16 executes repeatedly (step S3), every second for example, a calculation to determine the elongation Δl which remains to be applied to the strand 13A before the jack

15 is released and that the anchoring of the strand 13A is caused by the retraction of the keys in the anchoring. The data measured or determined on site necessary for this calculation are: the initial displacements ÏÏAI and _7 & previously determined (Step S2), the tension T of the strand measured using the sensor 15A, - the variation Δd of the straight distance between the anchorages A and B measured using the range finder 18, the origin of the Δd being taken at the time when the initial displacements are determined, that is to say just before the first strand 13 is threaded , the temperature θ _t0 r of the strand 13A measured using the sensor 20, the retraction of keys rc As the tensioning operation progresses, the value of the elongation Δl remaining to be applied to the strand 13A is displayed on the computer screen

16 and a signal can be sent to an automaton 23 controlling the jack 15 to release the latter as soon as Δl reaches the value zero, the re-entry of keys rc being taken into account.

At a given instant of the tensioning operation of the strand 13A, the zero voltage length L of the latter is obtained from a function similar to that used for the calculation of the theoretical length described above: L = Λ (Ea, q *, AB, T)

Ea here representing the axial stiffness of the strand, q * being equal to the linear weight q _t of the strand, increased by the contribution of the strand to support the linear weight q _g of the sheath 14: q * = q _t + q _g / i ( i strand number)

AB representing the relative position of the anchors, if they were perfectly installed: with / unitary vector joining anchors A and B.

The length at zero voltage L _θ , objective to be reached at the end of the adjustment operation under a temperature θ _{tor is} worth:

L _θ = L _th [l + D (θ _to r- θ _th )] π denoting the coefficient of expansion of the strand. The elongation Δl remaining to be applied to the strand 13A before releasing the jack 15 is finally given by:

Δl = L - L _θ + rc rc designating the value of the re-entry of keys (in the order of 4 to 7mm in practice). The strand 13A is then permanently anchored in the anchor A and the jack 15 is detached from it so that it can be used for the next strand 13.

As can be seen in FIG. 4, according to the second example of execution of the invention, steps S1 and S2 are executed in the same way as during the implementation of the first example.

However, this second exemplary embodiment differs from it in step S3 during which, instead of calculating the elongation value Δl, the value T representing the blocking voltage to be reached in the strand 13A is calculated before the 'we can proceed with anchoring.

Thus, from the values AB, q * and L _θ, the blocking voltage T _b | _oc from relationship:

It will be noted that the determination of the function T above may involve the same theory of the Elastic Chain described in the above-mentioned work, the problem to be solved being based on the search for the value of T instead of that of L.

The value of the blocking voltage T _b ι _QC calculated by the computer 16 is displayed in a window V2 of the screen, while the actual value of the voltage in the strand 13A measured using the sensor 15A is displayed simultaneously in another window VI. The blocking is carried out as soon as the two values in windows VI and V2 become equal. The process can possibly be stopped automatically by the automation 23 as soon as the condition of equality is reached. FIG. 5 represents a variant of telemetric device 18A intended to measure the variation in distance between the anchors A and B and which can also be used for the execution of the method according to the invention. In this case, an Invar® wire for example is fixed by one of its ends to the pylon 1 in the vicinity of the top anchor B. The other end of this wire passes over a pulley 24 mounted in the vicinity of the bottom anchor A and is attached to a mass 25. An electronic comparator 26 is placed on part 3A of the deck under construction and measures the variation in the vertical position of the mass 25 to allow the variation in distance between the anchors to be deduced therefrom A and B.

We can also consider other variants of the device used to measure the variation in distance between anchors A and B. Thus, the use of an opto-digital system makes it possible to determine, from the digital processing of an image carried out in time real, the evolution of the distance between a target and the instrument.

Claims

1. A method of tensioning a shroud (12) with multiple strands in which said strands (13, 13A) are placed one after the other between two anchors (A, B) integral with the structure, the method consisting in - pulling on one end of a strand (13A) from one (A) of the anchors, while the other end is fixed on the other anchor (B), to be measured continuously , the value of the tension in the strand (13A), and continuously testing a condition of end of tensioning of the strand (13A), this condition bringing into play an expression function of a predetermined parameter (Δd), characterized in that said predetermined parameter is the variation (Δd) of the distance separating said anchors (A, B).

2. Tensioning method according to claim 1, characterized in that it consists: a) in determining the theoretical value of the length at zero tension (L _th ) of the stay (12), as a function of: the total number (n) of strands (13) of the shroud (12), of the axial stiffness (Ea) and of the linear weight (q _t ) of each of the strands of the shroud (12), of the theoretical position (_o, ÎCBO) of the anchorages (A, B) as defined by the plans of the structure, values of the tension (T _pr ) of the guy wire (12) and displacements (UApr, UB _Pr of the anchorages provided for by the design calculations of the structure for a predetermined reference phase located after the tensioning operation of the shroud (12), b) to evaluate the initial displacements (Û _AI , û _BI ) of the anchors (A, B) as they appear just before laying the first strand of the guy (12), c) during the tensioning of each strand (13A) of the guy (12): continuously measuring said variation in distance (Δd) comp from step b), to implement a calculation loop to continuously test the condition of end of tensioning of the strand (13A,) using said expression as a function of said predetermined parameter (Δd), and d) blocking the strand (13A) during tensioning on the anchor (A) as soon as the end of tensioning condition of the strand (12, 13A) is satisfied.

3. Tensioning method according to claim 2, characterized in that said expression as a function of said predetermined parameter defines the remaining elongation (Δl) to be applied to the strand (13A) until the end of tensioning condition is satisfied.

4. Tensioning method according to claims 2 and 3, characterized in that said expression is defined by the following parameters: i) the stiffness (Ea) and the linear weight (q *) of the strand (13, 13A) , ii) the theoretical value of said length at zero voltage (L _th ), iii) said initial displacements (UAIJIBI), iiii the voltage measured in the strand (13, 13A), and iiiii) said variation in distance (Δd) and in that the strand is blocked, when the value of the elongation remaining to be applied (Δl) becomes equal to zero.

5. Tensioning method according to claim 4, characterized in that said expression is also defined by a value (rc) representing the return of the keys by which said strand (13, 13A) is anchored on its anchor (A).

6. Tensioning method according to claim 2, characterized in that said expression as a function of said predetermined parameter (Δd) defines the blocking voltage (T) that said strand must reach (13, 13A) before we can proceed to its anchoring.

7. Tensioning method according to claims 2 and 6, characterized in that said expression is defined by the following parameters: i) the stiffness (Ea) and the linear weight (q *) of the strand (13, 13A), ii) the theoretical value of said zero voltage length (Lth), iii) said initial displacements (AI, I7BJ), and iiii) said distance variation (Δd), and in that the strand is locked, when the measured value (V2) of the voltage applied to said strand (13, 13A) becomes equal to that of the voltage thus calculated

CD-

8. A method according to any one of claims 1 to 7, characterized in that said initial displacements (_., _7 &) are measured on the structure according to a procedure taking into account the tolerances for making said structure.

9. Tensioning method according to any one of claims 1 to

7, characterized in that said initial displacements (£ __, _ / _._) are determined from the results of the design calculations of the structure.

10. Tensioning method according to any one of claims 4 to 9, characterized in that, the guy (12) comprising a protective sheath (14), the method also consists: i) determining the theoretical value of said length at zero voltage

(Lt _h ) from the linear weight (q _g ) of said sheath (14), and ii) during the calculation relating to said condition of end of tensioning, to increase the linear weight of the strand (13A) being tensioning of a fraction (q _g / i) of the linear weight (q _g ) of the sheath (14).

11. Tensioning method according to any one of claims 2 to 10, characterized in that it also consists in the course of step c) to be taken into account, in the calculation relating to said condition of end of setting in tension, the temperature (θtor) of the strand being tensioned (13A).

12. Tensioning method according to any one of claims 2 to 11, characterized in that it also consists in the course of step b) to be taken into account in the determination of said initial displacements (ÛAI, ÏÏBI), the temperatures of the shrouds already installed on the structure (7 to 11) and of the structure itself (1 to 6).