FR2807519A1 - Determination of the resistance of an underground hollow structure such as a tunnel, gallery or large pipe to destructive compressive forces by placing a jack within the structure and application of forces against each end - Google Patents

Abstract

Method in which two opposing forces are applied to either side of a housing surface (3) at points (21, 22) at which a jack (10) is mounted against blocks (21, 22). The opposing forces are increased and the separation between the two points is determined respectively for each opposing force. A ratio is determined equal to the difference of the two separations divided by the two applied forces. The determined ratio is compared with similar experimental data to estimate the body's resistance to destruction. The invention also relates to a device for use with the above method.

Description

The present invention relates to methods for determining the resistance to destruction in a medium of a given nature, the body having a defined structure and having a hollow housing, which find a particularly advantageous application in the field of the determination of resistance to the destruction of structures such as tunnels, galleries, large pipes, etc.

The present invention also relates to the devices for implementing the methods denoted above.

11 is a bief? known methods to determine the given body resistance to its destruction. Such methods consist essentially in applying increasing intensities of opposing forces on the body, up to a predetermined value, hoping that it will not be destructive of the body.

 When a hollow body like, for example, a tunnel, a pipe, etc. has been buried in soil for some time, it is necessary to determine its state, for example its deformation and resistance to destruction. To do this, on the one hand it is possible to apply the two opposing forces only on the inner surface of the hollow body and, on the other hand it is of course very damaging to apply in this case forces that can prove to be destructive.

Also, the present invention aims to implement a method that overcomes at least a large part of the disadvantages of the processes of the prior art.

The present invention also aims to provide a device for carrying out the method according to the invention, to determine the resistance of a body to its destruction, when the body is located in a medium of a given nature, this body having a specific structure and having a hollow housing.

More specifically, the present invention relates to a method for determining the resistance of a body to its destruction, when the body is located in a medium of a given nature, said body having a specific structure and having a hollow housing, characterized by the fact that it consists in applying two opposing forces respectively in two first and second points of the surface of said housing, in increasing the intensity of the two opposing forces between two first and second values F, and F2, - determining the variation Al, and A12, with respect to an origin value, of the distance separating the two first and second points, respectively for the first intensity F, of the two opposing forces and for the second intensity F2, - to determine the ratio R between F2-F, and O12 - / \ 1 ,, - to compare the value of this ratio R with those of a set of values determined experimentally with bodies similar to said body and located in a medium similar to said medium and, depending on. this comparison, - to make first estimate of the resistance to the destruction of said body.

According to another characteristic of the present invention, the method further comprises - decreasingly decreasing the intensity of the two opposing forces, between the two said second and first values F2 and F ,, - to determine the variation 013, by to the same origin value, the distance separating the two first and second points, when the intensity of the two opposing forces has returned to the first value F ,, - to determine the ratio Q between F2 and A13 - A1 1, - to compare the value of this ratio Q with that of a set of values determined experimentally with bodies similar to said body and located in a medium similar to said medium and, based on this comparison, to make a second estimate of. the resistance to the destruction of said body, completing the first estimate.

The present invention also relates to a method for determining the resistance of a body to its destruction, when the body is located in a medium of a given nature, said body having a. defined structure and comprising a hollow housing, characterized in that it consists in: 1) effector at least two sequences of successive operations respectively consisting in - applying two opposing forces respectively in two first and second points of the surface of said housing, - increasing the intensity of the two opposing forces between two first and second values F1 and F2, and - determining the variation 41, and A12, with respect to an origin value, the distance separating the first and second two points, respectively for the first intensity F, of the two opposing forces and for the second intensity F2, II) to be determined, each sequence, the ratio R between. F2 - F; and 012 - <B> AI 1, </ B> III) then, in final operation, - to compare the values of the ratios R determined for all the sequences, with those of a set of values determined experimentally with bodies similar to said body and located in a medium similar to said medium as a function of. this comparison, - to make a third estimate of the resistance to the destruction of that body.

According to another characteristic of the present invention, the process further comprises I) during each sequence, to vary in a decreasing manner the intensity of the two opposing forces, between the two said second and first values FZ and FI, and determining the variation A13, with respect to the same origin value, of the distance separating the two first and second points, when the intensity of the two opposing forces has returned to the first value FI, II) to be determined, for each sequence, the ratio Q between F, and A13 III) then, in a final operation, - to compare the values of the ratios Q held-for all the sequences, with those of a set of values determined experimentally with bodies similar to the said body and located in a medium similar to said medium according to this comparison, - to make a fourth. estimate of. the resistance to the destruction of said body, completing the third estimate.

The present invention also relates to a device for carrying out the method according to the invention to determine the resistance of a body to its destruction, when the body is located in a medium of a nature. given, said body having a specific structure and having a hollow housing, the device being characterized in that it comprises a jack, said jack having two ends, means for supplying said cylinder with fluid under pressure, two pads shaped to take contact with the surface of said housing, means for mounting said two pads respectively at both ends of the cylinder, and means for measuring the distance variation between said two pads.

Other features and advantages of the invention will become apparent from the following description given with reference to the accompanying drawings for illustrative but not limiting purposes, in which Figure 1 shows, in form. schematic., a device for carrying out the method according to the invention, for determining the resistance to destruction of a body located in a medium of a given nature, this body having a specific structure and having a hollow housing and Figures 2 to 5 show diagrams for explaining the implementation of the method according to the invention.

Figure 1 is a schematic representation of a device 1 for carrying out the method according to the invention for determining the resistance of a body 2 to its destruction when the body 2 is located in a medium of a nature. given, this body having a specific structure and having a hollow housing 3. For example, this body may be a pipe consisting of a cylindrical tube constituting the hollow housing c, made for example of concrete, masonry or the like, and buried in a sandy soil 4 located below a road 5 on which is able to move motor vehicles such as trucks or the like.

In a schematic manner, the device comprises a cylinder 10 with two ends 11, 12, means 13 for supplying the cylinder with fluid under pressure, for example a source of a fluid such as oil, associated with a pump, a compressor or analogous whose output pressure can be modulated, two pads 14, 15 shaped to contact the surface of the housing 3 of the body 2, means for mounting the two pads 14, 15 respectively to the two ends 11, 12 of the jack 10, and means 16 for measuring the distance variation between the two pads 14, 15, for example a metric comparator which is known itself and which will therefore not be described here. The jack 10 may for example be single-acting, comprising in this case a cylinder and a single piston rod, the two ends 11, 12 then being respectively constituted by one end of the cylinder and the outer end of the piston rod. According to one. Another advantageous embodiment, as schematically illustrated in Figures 1, 4 and 5, the cylinder 10 may be double-acting, comprising in this case a cylinder and two piston rods mounted in opposition, the two ends 11, 12 then being respectively constituted by the outer ends of the two piston rods.

The method consists firstly in applying two opposing forces respectively in two first and second points 21, 22 of the surface of the housing 3. These forces are exerted by the pads 14, 15 which are pushed by the jack 10 by means of the fluid under pressure. In this way, by knowing the value of the pressure of the fluid and the value of the surface of the pads, it is easy to know perfectly the intensity of the forces applied to the two points 21, 22 of the surface of the housing 3 on which are in support the pads 14, 15. The. The process then consists in increasing the intensity of the variation. two opposing forces, between two first and second values F, and F2. The first value is for example equal to zero Newton, as in FIG. 3, but it can also not be zero, like FIG.

Simultaneously, variations <B> AI, </ B> and A12 are determined with respect to an origin value, the distance separating the two first and second points 21, 22, ie in fact the distance separating two pads 14, 15, respectively for the first intensity F, of the two opposing forces and for the second intensity F2, as more particularly explained in FIG. 2. This determination is carried out, for example, by means of the metric comparator 16.

The method then consists in determining the ratio R between F 1) - F1 and A12 - A1 ,, and then comparing the value of this ratio R with those of a set of values determined experimentally with bodies similar to the body 2 and located in a medium similar to the medium in which the body 2 is located and, based on this comparison, to make a first estimate of the resistance to destruction of the body 2. at least in the areas surrounding the two points 21; 22 on which are supported the two pads 14, 15.

In order to supplement or refine the first estimate, the method further comprises decreasingly decreasing the intensity of the two opposing forces between the first two second values FZ and FI, FIG. 2, and then determining the variation A13, relative to the same origin value, the distance separating the two first and second points when the intensity of the two opposing forces has returned to the first value FI.

FIGS. 2 and 3, the values 41, and Al 3 are different, but it is obvious that they can be equal if the force F 2 did not cause the elastic deformation of the body 2 to be exceeded to arrive in the plastic deformation P , figure 2.

This value A13 having been determined, the. ratio Q between FZ and A13 - is calculated and the value of this ratio Q is compared with those of a set of values determined experimentally with bodies similar to said body and located in a medium similar to said medium and, according to this comparison, a second estimate of the resistance to the destruction of the body is made, completing the first estimate.

In carrying out the method described above, the value F is empirically predetermined. However, for greater security, it can advantageously be determined experimentally.

For this, the method consists. to define the curve representative of the variation of the intensity of the opposing forces applied to the points 21, 22, as a function of the variation of the distance separating these two points. The value F2 is determined just. after the point which corresponds to a noticeable change in the slope of the curve. This point referenced X in Figure 2 separates the curve portion E which represents an elastic body deformation, of the curved portion P which represents the beginning of the plastic deformation of this body.

For the implementation of the method according to the invention, the variation of the intensity of the two opposing forces can be of any shape but it is of course advantageous that it be carried out continuously, as well as when it increases between two values F, and F2, only when it decreases between F2 and F ,.

The method described above makes it possible to determine the resistance to the destruction of a body between the two points 21 and 22, but does not make it possible to determine which of these two points belongs to the wall zone of the housing which is the weakest, that is, the one with the weakest response to a stress on it.

Also, with particular reference to FIGS. 4 and 5, the method further consists, in order to determine, between the two points, which belongs to the zone of the body having the lowest resistance to destruction, in a first phase (Figure 4), to apply two opposing forces of different intensities of F ,,, and Fm, respectively at the first point 21 and the second point 22, and to determine the value Al (); of the variation of distance separating these two first and second points.

The method then consists, in a second phase (FIG. 5), of applying the two opposing forces of values Fm and FM in inverse fashion to that of the first phase, that is to say at the second point 22 and at the second point respectively. first point 21, and to determine the new value AI02 of the variation of the distance separating these two first and second points.

The method then consists in comparing the values O10 and A102 to determine, between the two points, which belongs to the zone of the body having the lowest resistance to destruction.

By way of example, with reference to FIGS. 4 and 5, if the value Aloi is greater than the value A102, the weakest wall zone is that which is on the part of FIGS. 4 and 5 referenced G. If the value 010, is less than the value o102, the weakest wall area. is the one found on part D of these two figures 4 and 5.

This result can be demonstrated without difficulty and its demonstration will not be repeated here, it is the scope of the person skilled in the art.

But in addition, if the intensities FM and F "are known, which is easy, knowing the pressure value exerted by the pads 14, 15 and the value of the surfaces of these two pads, it is even possible to determine, with a good approximation, the amplitude of the deformations in the zones of the points 21 and 22 as a function of the values Aloi and A102 defined above.This determination is made by mathematical calculation, and will not be developed for the simple sake of not weighing down As a result, the surfaces of the two pads 14, 15 of the device 1 which are able to make contact with the housing wall 3 are defined in a given ratio.

The process described above gives good results. However, in order to further refine these results, it is advantageous to proceed as described hereinafter in particular in FIG.

At least two successive sequences of operations are carried out respectively consisting in: applying two opposing forces respectively in two first and second points of the surface of the housing 3, in increasing variation in the intensity of the two opposing forces, between two first and second second values FI and F2, (F1 'and F2', ...), and to determine the variations <B> AI, </ B> and A12, (Al, 'and A12', ...), relative to an origin value, of the distance separating the two first and second points, respecting for the first intensity F, the two opposing forces and for the second intensity F ,.

For each sequence, one determines the ratio R, (R ', ...) between F2 - F <B> I </ B> and <B> <U> Al, </ U> - A],. </ B> Finally, in a final operation, the values of the ratios R (R ', ...) determined for the set of sequences are compared with those of a set of values determined experimentally with bodies similar to said body and located in a medium similar to the medium and, based on this comparison, a third estimate of the destruction resistance of the body 2 is made.

Preferably, the method may furthermore consist, in each sequence, in decreasingly varying the intensity of the two opposing forces, between the second and first values F 2 and F 1, and in determining the variation A 13, by relative to the same origin value, of the distance separating the two first and second points when the intensity of the two opposing forces has returned to the first value F ,. It is then necessary to determine, for each sequence, the ratio Q between F2 and AI3-A1] and, in a final operation, to compare the values of the ratios Q determined for all the sequences, with those of a set of. values determined experimentally with bodies similar to the body 2 and located in a medium similar to the medium 4. Based on this comparison, it is possible to make a fourth estimate of the destruction resistance of the body 2, completing the third estimate.

The results of the comparisons mentioned above are very revealing of the resistance of a body to its destruction. Indeed, the Applicant has determined that there is always some similarity between bodies of the same structure that are placed in the same environment. Their resistance to destruction, under these conditions, is still substantially the same. Thus, the Applicant has determined that the parameters mentioned above, in particular the R and Q ratios, are well representative of this behavior. They can, therefore. to be used by comparison, to estimate the resistance of a body to its destruction.

This estimate is generally used to decide whether or not it is necessary to undertake, for example, maintenance, reconstruction, solidification, repair, etc., and even to design new bodies in predetermined places, for example, structures such as those mentioned in the preamble of the present description.

Claims (11)

1. A method for determining the resistance of a body to its destruction, when said body is located in a medium of a given nature, said body having a specific structure and having a hollow housing, characterized in that it consists - to apply two opposing forces respectively in two first second points of the surface of said housing, - to vary increasing the intensity of the two opposing forces, between two first and second values F1 and F2, - to determine the variation 011 and 012, with respect to an origin value, of the distance separating the two first and second points, respectively for the first intensity F, of the two opposing forces and for the second intensity F2, to determine the ratio R between F2-F, and A12 - A11, - to compare the value of this ratio R with those of a set of values determined experimentally with. bodies similar to said body and located in a medium similar to said medium and, based on this comparison, - to make first estimate of the resistance to the destruction of said body. 2. Method according to claim 1, characterized in that it further consists in decreasing the intensity of the two opposing forces between said second and first values F 2 and F 2 to determine the variation A13, with respect to the same origin value, of the distance separating the two first and second points, when the intensity of the two opposing forces has returned to the first value F1, - to determine the ratio Q between F2 and A13 - A1 to compare the value of this ratio Q with that of a set of values determined experimentally with. bodies similar to said body and located in a medium similar to said medium and, based on this comparison, - to make second estimate of the resistance to the destruction of said body, completing the first estimate. 3. Method according to one of claims 1 and 2, characterized in that it consists - to define the curve representative of the variation of the intensity of the opposing forces as a function of the variation of the distance between the first two and second points, and - determining second FZ value of the intensity of the two opposing forces as a function of a significant change in the slope of said curve. 4. Method according to one of claims 1 to 3, characterized in that the first value FI of the intensity of the two opposing forces is zero Newton. 5. Method according to one of claims 1 to 4, characterized in that the increasing variation of the intensity of the two opposing forces is effected continuously between two first and second values F, and F2. 6. Method according to claim 2 and one of claims 1, 3, 4 and 5, characterized in that the decreasing variation of the intensity of the two opposing forces is effected continuously between the two second and first values FZ. and F,. 7. Method according to one of claims 1 to 6, characterized in that, in the. between two points, which belongs to the zone of the body having the lowest resistance to destruction, it consists - in a first phase - in applying two opposing forces of different intensities of values and FM, respectively in the first one. point and at the second point, and - to determine the value <B> AI (), </ B> of the variation of the distance separating the two first and second points, - in a second phase, - to apply the two said forces antagonists of values Fm and FM, respectively at the second point and at the first point, and - at determining the value Alo2 of the variation of the distance separating the first and second points, - in a third phase, comparing the values A1 () , and AI02 to determine, between the two points, the one that belongs to the area of the body with the lowest resistance to destruction. 8. A method for determining the resistance of a body to its destruction, when said body is located in a medium of a given nature, said body having a specific structure and having a hollow housing, characterized in that it consists I) effecter at least two sequences of successive operations, each operation consisting of - to apply two forces opposed respectively to two first and second points of the surface of said housing, - to vary increasing the intensity of the two opposing forces, between two first and second values FI and F2, - determining the variation <B> AI, </ B> A12, with respect to an origin value, of the distance separating the two first and second points, respectively for the first intensity F of the two opposing forces and for the second intensity F2, II) to be determined, for each sequence, ratio R between F2 - F1 and A12 - Alt, III) then, in a final operation, - to comp derive the values of the ratios R determined for all the sequences, with those of a set of values determined experimentally with bodies similar to said body and situated in a medium similar to said medium and, as a function of this. comparison, - to make a third estimate of the resistance to the destruction of said body. 9. A method according to claim 8, characterized in that it further comprises I) during each sequence, - to vary in a decreasing manner the intensity of the two opposing forces, between the two said second and first values F2 and F1, and - to determine the variation A13, with respect to the same origin value, of the distance separating the two first and second points, when the intensity of the two opposing forces has returned to the first value FI, II) to be determined, for each sequence, ratio Q between F2 and o13 - 01 ,, III) then, in a final operation, - to compare the values of the ratios Q determined for the set of sequences, with those of a set of values determined experimentally with bodies similar to said body and located in a medium similar to said medium and, based on this comparison, - to make a fourth estimate of the resistance to the destruction of said body, completing the third I estimate. 10. Device for putting on. in-use the method according to one of the preceding claims, characterized in that it comprises a jack (10), said jack having two ends (1, 12), means (13) for supplying said cylinder with fluid under pressure two shoes (14, 15) shaped to make contact, in at least the first and second points (21, with the surface of said housing (3), means for mounting the two said pads respectively at both ends of the jack, and means (16) for measuring the distance variation between said two pads. 11. Device according to claim 10, characterized in that the surfaces of said two pads (14, 15) able to make contact, at least the first and second points (21, 22), with the surface of said housing are in a given report.