IT202000011800A1 - METHOD FOR INCREASING THE BEARING CAPACITY OF A SOIL - Google Patents

Description

DESCRIPTION

annexed to a patent application for an industrial invention entitled:

METHOD TO INCREASE THE CAPACITY? SOIL CARRIER

DESCRIPTION

The present invention relates to a method for increasing the capacity? carrier of a land, to be used in the building sector.

To increase the capacity? carrier of a land? a deeply felt need both in the context of the construction of new buildings and in the context of restoration interventions in the event of subsidence beneath buildings or other existing building structures.

Over time have been designed, tested and used many methods? different to increase the capacity? carrier of land, among which we remember the injection of resins pi? or less expanding, the injection of cement mortars, the construction of foundation pilings, eco...

The present invention proposes a solution with intermediate characteristics between the injection of resins and the construction of foundation pilings.

Currently the methods pi? common for the construction of foundation pilings involve the use of metal poles, concrete poles or poles made with expanding resins.

The driving of metal piles or micropiles can take place with or without removal of material. In the first case, a hole is made in the ground into which the post is then lowered; around the pole we proceed to the filling with earth, gravel, sand or concrete. In the second case the piles are driven into the ground by beating or by continuous pressure.

Both concrete poles and those made with expanding resins, on the other hand, require the creation of a hole in the ground, in some cases the compaction of the walls of the hole, and the subsequent filling of the hole with concrete or resins in a liquid state.

Although all allow to increase the capacity? load-bearing of the soils, all the methods used up to now are not free from drawbacks.

Some are particularly noisy to carry out (for example those with hammer-fixing or those that require the execution of drilling), some have a significant environmental impact (those that inject resins or concrete in depth), some are particularly expensive (a due to the complexity of the intervention or due to the material used - for example in the case of the use of disposable steel poles), some require large working spaces and are therefore not compatible with interventions to be carried out inside existing buildings (for example such as those that require the use of bulky drills). It must also be taken into account that building a foundation piling, in many cases involves the need to to put down hundreds of poles.

Not all the known methods then allow the lift of the ground to be increased in the same way, nor? to build relatively deep foundation pilings (for example in order to reach relatively deep rock layers).

In this context, the technical task underlying the present invention ? to develop a method to increase the capacity? carrier of a soil which provides an alternative to the known methods.

? in particular the technical task of the present invention is to develop a method for increasing the capacity? carrier of a terrain that is relatively silent to implement and has a relatively low cost of execution.

? further technical task of the present invention is to develop a method for increasing the capacity? carrier of a land that is easy to build.

Not last, ? technical task of the present invention is to develop a method for increasing the capacity? load-bearing soil that allows for consolidation until reaching relatively deep and consistent rock layers.

The technical task and the aims indicated are substantially achieved by a method for increasing the capacity? bearing of a ground in accordance with what is described in the accompanying claims.

Further characteristics and advantages of the present invention will appear more evident from the detailed description of some preferred, but not exclusive, embodiments of a method for increasing the capacity of the present invention. load-bearing ground illustrated in the attached drawings, in which:

figure 1 shows, in schematic front view in axial section, a probe usable in the context of the present invention, associated with a hydraulic thrust device;

- figure 2 schematically shows the beginning of a step for inserting the probe into the ground, in accordance with the method object of the present invention;

- figures 3 to 9 schematically show the continuation of the insertion phase until the complete construction of a well;

- figure 10 schematically shows a subsequent phase of partial lifting of the probe;

- figure 11 schematically shows a subsequent step of inserting a granular material under the probe;

- figure 12 schematically shows a subsequent step of compressing the granular material carried out by means of the probe;

- figure 13 shows an enlarged detail of figure 12;

- figure 14 schematically shows a subsequent step for inserting further granular material, carried out after a repetition of the previous lifting step;

- figure 15 schematically shows a subsequent new compression step; And

- figure 16 shows the result obtainable by repeating the insertion and compression phases, gradually lifting more and more? the probe in the well.

The method to increase the capacity? carrier of a soil object of the present invention, in its most effective embodiment? general, includes the following operational phases:

a step in which a well 1 is created in the ground having a constant section, carried out without removing any material; And

a phase in which the well 1 is filled cos? created with granular material 2 compacted.

Well 1? generally made vertical (as in the embodiments illustrated in the accompanying figures and described hereinafter) or slightly inclined with respect to the vertical.

In the preferred embodiment, the step of creating the well 1 provides for a step of inserting a probe 3 into the ground 14, during which the probe 3 is inserted. inserted into the soil 14 under pressure and without removing any material. Advantageously, the pressure insertion of the probe 3 ? performed with a hydraulic device 4, which can? include one or more hydraulic actuators, and what ? associated with a feedback able to provide the necessary reaction for the application of the desired force on the probe 3. This feedback (not shown) can? be constituted by a special ballast, by an existing foundation or by the combination of the two (associating the ballast with the foundation). In case the foundation is used, the hydraulic device 4 will have to be fixed to the foundation, while in the case of use only of a ballast, the latter can? be positioned directly on a support frame of the hydraulic device 4. Particularly advantageous, pu? be that the hydraulic device 4 is mounted on a ballasted vehicle.

In accordance with the preferred embodiment of the present invention, during the insertion phase the hydraulic device 4 exerts a first force on the probe 3, which can be both substantially constant over time and variable over time, depending on the project choices. As an example can? be provided a first maximum force to be applied to the probe 3, but also that the first force applied is such as to determine a speed? of insertion of the probe 3 of the soil 14 not excessive (for example not higher than a predefined limit speed). Consequently, the application of the first force can? foresee, at the beginning, a gradual growth of? intensity? of the first force, until one of the following conditions occurs: o the applied force ? equal to the first maximum force, or the speed? of inserting the probe 3 into the ground 14 ? equal or close to the speed? default limit. At that point, the insertion continues with the? intensity? of the first force cos? determined, until the entry conditions change. For example, if the applied force is not still equal to the first maximum force, and the speed? of insertion decreases, the? intensity? of the force can? be increased. Otherwise, if the speed? of insertion increases and reaches or exceeds the speed? pre-set limit, the? intensity? of the first force must be decreased.

Preferably, however, the insertion of the probe 3 into the soil 14 takes place slowly and gradually with insertion times of not less than 40 seconds per meter of advance, advantageously comprised between 40 and 60 seconds.

In accordance with the preferred embodiment of the present invention, however, during the insertion phase the hydraulic device 4 exerts the first force on the probe 3 in a protracted manner over time. In other words, any insertions of probes into the ground 14 performed by impact (which use impulsive forces), so? just as any executions which provide for the insertion of the probe 3 into a hole made by drilling the ground 14 by removing material are not included.

Advantageously, the first force ? generated by applying a first working pressure to a working liquid of the hydraulic device 4 (the control of the pressure is in fact much simpler than the control of the axial force actually applied to the probe 3).

In a preferred embodiment, for the insertion step (and, as better explained below, also for the subsequent steps) a probe 3 is used which comprises a straight stem 5 and a lower head 6, advantageously with the lower head 6 which protrudes in the radial direction, with respect to a central axis of the stem 5, more? of the stem 5, so that the ground 14 opposes resistance to the advancement of the probe 3 only at the lower head 6.

Furthermore, in some preferred embodiments, a probe 3 is used to carry out the insertion step which comprises a stem 5 constituted by a plurality of probes. of tubular bodies 7, which can be connected one to the other in succession to increase the length of the probe 3 as the probe 3 penetrates the ground 14. Advantageously, the connection of each tubular body 7 takes place by screwing it to the rest of the stem 5 already? format.

Consequently, in these implementation forms, the insertion phase provides for a plurality of phases of partial insertion, alternating with a plurality? of lengthening phases of the probe 3. In each phase of partial insertion, the probe 3 is inserted into the ground 14 for a length equal to that of one or more? tubular bodies 7, advantageously equal to the length of the tubular bodies 7 which were added in the previous lengthening step. In each phase of elongation of the probe 3, in fact, one or more? tubular bodies 7 are added to the upper part of the stem 5 (figures 3-4 and 6-7), after this ? momentarily released by the hydraulic device 4.

As schematically illustrated in the accompanying figures, before the insertion step, the hydraulic device 4 is positioned in such a way as to be axially aligned vertically with the rod 5, preferably in such a way that in its retracted position it is at a distance from the ground equal at the height of the first piece of probe 3, consisting of the lower head 6 and one or more? tubular bodies 7 (in a preferred embodiment, the tubular bodies 7 have a length of about 1 m and the space between the lower head 6 resting on the ground and the operating part of the hydraulic device 4 is equal to slightly more than the length of a tubular body 7). Once the latter have been positioned under the hydraulic device 4, the active part of the hydraulic device 4 is rested, preferably fixed, to the upper part of the tubular bodies 7 present.

The hydraulic device 4 is then actuated until, following the insertion of the lower head 6 into the ground 14, the upper part of the tubular bodies 7 ? dropped sufficiently to allow the connection of one or more? new tubular bodies 7 (figure 4), after detachment from the hydraulic device 4 and return of the hydraulic device 4 to its starting position (figure 3). By repeating this operation, a plurality? of times, ? Is it possible to reach depth? also very high driving force. In some embodiments, the tubular bodies 7 have lengths between 0.5 m and 2 m, preferably between 0.75 m and 1.25 m.

In some embodiments, the insertion phase ? performed by maintaining a disposable plug 8 associated with the lower head 6 of the probe 3, plug 8 intended to be subsequently left at the bottom of the well 1 at the time of filling with the compacted granular material 2. Depending on the needs, the disposable cap 8 can? have a flat or convex bottom surface (e.g. hemispherical, conical, pyramidal, eco...). Depending on the implementation forms, during the insertion phase pu? it must be foreseen both that any axial rotations of the probe 3 are inhibited, and that they are permitted, and that they are imposed by the hydraulic device 4.

As for the duration of the insertion phase, and the depth? of well 1, different criteria can be adopted. In some applications, the insertion phase continues until the first force (at its maximum intensity value?) exerted by the hydraulic device 4 on the probe 3 ? insufficient to overcome the reaction force exerted by the ground 14, so that? a further advancement of the probe 3 is impossible with the foreseen working conditions. In some applications, on the other hand, the insertion phase continues until reaching a depth? predetermined decided in the project phase. As regards the filling step, in accordance with the preferred embodiment of the present invention, ? provision is made for the filling to be gradual, ie that the granular material 2 is introduced into the well 1 a little at a time, and that after each introduction the granular material 2 is compacted.

For this purpose, in its preferred embodiment, once the insertion phase (figure 9) has been completed, the method provides for a lifting phase during which the probe 3 in the well 1 is raised vertically, by an amount predetermined what? however equal only to a fraction of the depth? total of well 1. If ? Is the disposable cap 8 present, during the first execution of the lifting phase (as will be seen below, the phase is in fact repeated several times), is the disposable cap 8 ? left at the bottom of well 1 (figure 10).

In some embodiments, the entity? lifting speed of probe 3 during each lifting phase ? between 0.1 m and 2 m, preferably between 0.3 m and 1 m.

If the stem 5 of the probe 3 comprises a plurality? of 7 tubular bodies connected one to the other, the entity? of the lift? advantageously equal to the length of the top tubular body 7 (or tubular bodies 7).

Following the lifting phase, in well 1 you can? identify its section 9 to be compacted, which extends between the probe 3 (that is, between the lower head 6) and the bottom of the well 1 (figure 10).

At this point ? in fact, a compaction phase is provided, which is divided at least into a filling phase and a compression phase.

During the filling step, a granular material 2 is introduced into the portion 9 of the well 1 to be compacted, preferably an inert material such as gravel or sand.

For this purpose probe 3 ? advantageously equipped with an inlet duct 10 formed in the stem 5 and in the head, and which extends from an inlet 11 located at the top? of the probe 3, up to an outlet mouth 12 obtained in the lower face of the lower head 6. If the probe 3 comprises a plurality? of tubular bodies 7, each of them defines a section of the inlet duct 10. The outlet mouth 12 advantageously has a passage section (measured perpendicular to the axis of the probe 3) clearly smaller than the cross section of the well 1 (and therefore of the lower head 6). In some embodiments, the passage section of the outlet mouth 12 is comprised between a quarter and a tenth of the cross section of the well 1. The use of the disposable plug 8 is? recommended in the case of the presence of the outlet mouth 12, to prevent the soil 14 from clogging the inlet duct 10 following execution of the insertion phase. The inlet duct 10 preferably has a constant passage section and is sufficiently greater than the particle size of the granular material 2 to avoid the risk that the granular material 2 may obstruct the inlet duct 10. Preferably, however, the granular material 2? spheroidal type and ? dry, to reduce the risk of blockages.

In the embodiment illustrated in the accompanying figures, the inlet duct 10 also extends into the hydraulic device which defines the inlet 11.

The feed of the granular material 2 to the inlet duct 10 can be done simply by gravity, by positioning a suitable hopper 13 in connection with the inlet 11.

Depending on the needs, the phase of inserting the material can be performed both at the end of the lifting phase (figures 10 and 11), and simultaneously with the lifting phase. In this second case, the portion 9 of the well 1 to be compacted fills up with material as the probe 3 frees it.

The step of compressing the granular material 2 previously inserted in the section to be compacted 9 of the well 1,? advantageously performed by means of the probe 3 and the hydraulic device 4, which continuously exerts a second downward force on the probe 3. It should be noted that thanks to the reduced size of the outlet mouth 12 with respect to the overall cross section of the head, the presence of the outlet mouth 12 does not affect the effectiveness of the compression action (there is no significant rise of granular material 2 in the inlet duct 10). In the accompanying figures, does the lower face of the probe 3 ? substantially flat, but other shapes are also possible.

Even the compression phase? preferably turn slowly and gradually with speed? descent of probe 3 similar to those of the insertion phase. The second force can then be applied with intensity? gradually increasing over time, until a pre-set maximum value is reached. Also the second force ? advantageously generated by applying a second working pressure to the working liquid of the hydraulic device 4.

In many applications the compression phase ? performed by applying a second force which, at least in its maximum value (if variable), ? higher than the first force.

In some embodiments, the constipation step ? considered terminated only when you ? reached a predefined compaction condition.

Advantageously, the default constipation condition ? the one that occurs when the second force that acts during the compression phase (therefore at its maximum value, if variable) ? insufficient to determine a further descent of the probe 3, provided that the hydraulic device 4 has not reached the end of its stroke (that is, has not returned to the position it was in before the previous lifting phase).

Otherwise, if before reaching the compaction condition, probe 3 reaches the position it was in before the previous lifting phase, ? a repetition of both the lifting phase (if there were more than one, the one performed immediately before the insertion phase), and the filling and compression phases is foreseen. The effect of the compression phase? that of causing part of the granular material 2 to be driven into the soil 14 surrounding the well 1. Consequently, more? ? yielding ground 14, major ? the quantity? of granular material 2 that pu? stick to it before it is possible to reach the condition of constipation. Therefore, more ? the ground 14 that surrounds the stretch to be compacted 9 on which you are working is yielding, more? times will be It is necessary to repeat the lift, fill and compress steps before the default compaction condition is achieved.

Advantageously, moreover, the same steps are repeated more than once. times until when? compacted the entire section to be compacted 9 created with the first lifting phase. By way of example, figure 14 shows the case in which after the first execution of the filling phase and of the compression phase, ? it was possible to reach the predefined compaction condition as regards the lower part of the section to be compacted 9. At that point, without changing the lifting height of the probe 3, the lifting, filling and compression phases are repeated for the upper part of the section to be constipated 9.

In accordance with the present invention, then, once the portion to be compacted 9 is been effectively compacted, the method involves repeating, in succession, the lifting phase to create a new section to be compacted 9 of well 1, between the probe 3 and the previously compacted material, and the compaction phase in correspondence with the section to be compacted 9 what? created, gradually going up well 1 , until well 1 is not ? been filled with granular material 2 compacted to a predetermined level. In figure 16 is, schematically, illustrated the result that can be obtain.

Increasing the second force as you go up well 1 ? it is also possible to gradually increase the penetration of the granular material 2 into the walls of the well 1 obtaining an overall shape of the compacted material approximately in the form of a truncated cone (with the tip of the cone downwards).

In the preferred embodiments, compaction takes place for an entire section to be compacted 9 at a time. To go from one stretch to be constipated 9 to the next, pu? is in fact advantageously provided for the removal of a tubular body 7 from the end? superior.

Furthermore, using a hopper 13 associated with the inlet mouth 11 of the granular material 2 in the inlet duct 10, and always keeping it full,? It is possible to carry out the lifting, filling and compression phases in succession, without having to worry about the granular material 2, which could feed itself on the section to be compacted 9, at each lifting of the probe 3, by simple gravity. As ? evident, there? is valid only for all the time during which it is not ? necessary to remove a tubular body 7, operation for which? on the other hand, it is inevitable to interrupt the flow of granular material 2 from the hopper 13 to the inlet duct 10.

In the united figures ? however represented (schematically) the case in which there ? feed of granular material 2 during the compression step.

The method to increase the capacity? carrier of a ground 14 described up to now, pu? find advantageous application also in the context of a method for raising floors or foundations.

In that case, in fact, the method described so far can? be primarily used to increase the capacity? load bearing of the soil 14 underlying the pavement or foundation.

Next, if you don't ? already done before, the hydraulic device 4 is bound to the pavement or foundation to be lifted (basically to use it as a feedback for the force applied to the probe 3). The probe 3 is placed on the compacted granular material 2 and a force sufficient to lift the pavement or foundation is applied to the probe 3, by means of the hydraulic device 4, and this continues until the pavement or foundation reaches a predetermined height.

Depending on how? the compaction of the granular material has been carried out 2, the force required to lift the pavement or foundation can? be equal to, less than or greater than the second force.

Moreover, in the case of use in the context of a lifting method of this type, pu? be advantageous to ballast the pavement or the foundation during the method of increasing the capacity? bearing ground 14 (using the paving or the ballasted foundation as a reference), and remove the ballast when you want to proceed with the lifting. Once the pavement or the foundation ? been brought to the predetermined quota? advantageously foreseen that it is fixed at this quota according to any modality? known commonly used in lifting operations.

It should be noted that what has been described so far with reference to the construction of a single well 1 and its compaction, in the ordinary applications of construction of a foundation piling, must actually? be repeated a plurality? of times (tens or even hundreds).

The present invention achieves important advantages.

Thanks to the present invention ? was it possible to develop a method to increase the capacity? carrier of a land 14 which on one side? extremely silent to put into practice and which, on the other hand, has a relatively low execution cost (the inert granular material is among the cheapest that can be used in construction).

It ? moreover, it is easy to implement and allows for consolidations that reach deep rock layers (even at a depth of 30 metres?). Last but not least, the method described pu? be easily calibrated to the needs of the individual project; ? sufficient to vary the forces applied to the probe in the various phases, and the quantity? of granular material used, to increase pi? or less the capacity? soil bearing 14.

The invention so? conceived ? susceptible to numerous modifications and variations, all falling within the scope of the inventive concept which characterizes it.

All the details can be replaced by other technically equivalent ones and the materials used, as well as? the shapes and dimensions of the various components may be any according to the requirements.

Claims (12)

1. Method to increase capacity? carrier of a ground (14), comprising the following operational phases: a step of inserting a probe (3) into a soil (14), performed without removing any material, during which the probe (3) ? inserted into the ground (14) under pressure, to create a well (1) in the ground (14) that has a constant section, in which the pressure insertion of the probe (3) ? performed with a hydraulic device (4) which exerts, over time, a first force on the probe (3), and in which the hydraulic device (4) ? also associated with a striker which provides the necessary reaction for the application of the force on the probe (3); And a lifting phase, performed after the insertion phase, during which the probe (3) is raised in the well (1), by an entity? predetermined equal to a fraction of a depth? total of the well (1); following the lifting phase, in the well (1), below the borehole (3) a section to be compacted (9) can be identified; a compaction phase which includes at least a filling phase, in which a granular material (2) is inserted into the section to be compacted (9) of the well (1), and a compression phase of the granular material (2) previously inserted in the section to be compacted (9) of the well (1), performed by means of the probe (3) and by means of the hydraulic device (4) which continuously exerts a second downward force on the probe (3); and in which, once the said section to be compacted (9) of the well (1) ? been compacted, and until the well (1) is not? been filled with granular material (2) compacted up to a predetermined level, the method then provides for the repetition, in succession, of the lifting phase to create a section to be compacted (9) between the probe (3) and the previously compacted material, and of the compaction phase in correspondence with the section to be compacted (9) of the well (1) so? created. 2. Method according to claim 1 wherein a probe (3) is used which comprises a straight stem (5) and a lower head (6), and wherein an inlet duct (10) ? obtained in the stem (5) and in the head, the filling phase being performed by feeding the granular material (2) to the section to be compacted (9) through the inlet duct (10). 3. Method according to claim 2 wherein the lower head (6) protrudes more radially than the stem (5), with respect to a central axis of the inlet duct (10). 4. Method according to any one of the claims from 1 to 3 in which a probe (3) is used which comprises a stem (5) constituted by a plurality of of tubular bodies (7) which can be connected in succession to one another to increase the length of the probe (3), and whose insertion phase provides for a plurality of partial insertion phases, in each of which the probe (3) is inserted into the ground (14) for a length equal to that of one or more? tubular bodies (7), alternating with a plurality? of lengthening phases of the probe (3), during each of which one or more? tubular bodies (7) are added to the top of the stem (5). 5. A method according to claim 1 or 4 wherein the step of inserting ? performed while maintaining a disposable plug (8) associated with the lower part of the probe (3), and in which, during the first execution of the lifting phase, the disposable plug (8) ? left at the bottom of the well (1). 6. A method according to any one of claims 1 to 5 wherein the insertion step continues until the reaction force exerted by the ground (14) on the probe (3) ? equal to the first force, or until reaching a depth? predetermined. The method according to any one of claims 1 to 6, wherein, respectively during the insertion step and during the compression steps, the first force and the second force are generated by respectively applying a first working pressure and a second working pressure work to a working liquid of the hydraulic device (4). 8. Method according to any one of claims from 1 to 7 in which during each lifting phase the probe (3) in the well (1) is raised by an amount? between 0.1 m and 2 m, preferably between 0.3 m and 1 m. 9. A method according to any one of claims 1 to 8 wherein each compaction step is considered finished when? reached a condition of predefined compaction, in which the second force that acts during the compression phase? insufficient to determine a further descent of the probe (3), and in which if, before reaching the compaction condition, the probe (3) reaches a position in which it was before the previous lifting phase, the compaction phase foresees a repetition of the lifting phase performed immediately before the insertion phase, and repetition of the filling and compression phases. 10. A method according to any one of claims 1 to 9 wherein the hydraulic device (4) is fixed to a stop consisting of a foundation or a mobile ballast. 11. A method according to any one of claims 1 to 10 wherein the compression step is performed by applying a second force greater than the first force. 12. Method for raising pavements or foundations, including the following operational steps: increase capacity? bearing ground (14) underlying a pavement or a foundation, using a method in accordance with any one of claims 1 to 11; tie the hydraulic device (4) to the pavement or foundation to use it as a reference; rest the probe (3) on the compacted granular material (2); apply on the probe (3) through the hydraulic device (4) a force sufficient to lift the pavement or foundation up to a predetermined height; fix the flooring or foundation at the predetermined height.