The present invention relates to the field of reinforcing ground.
The invention relates more precisely to a method of making a reinforced structure in ground, such as, for example: a pile, a micropile, or indeed a reinforced structure for an umbrella vault.
Generally, making a pile comprises a step of making a borehole, a step of introducing a reinforcing element into the borehole, and a step of putting a sealing grout into place, at the end of which a pile type reinforced structure is obtained.
Although that traditional method of fabricating a reinforced structure gives entire satisfaction, it is relatively lengthy to perform because it requires different tooling for making the borehole, for introducing the reinforcing element, and for concreting, as a function of the terrains in presence and of the technique used.
An object of the present invention is to propose a method of making a reinforced structure in ground that is faster than traditional methods.
The invention achieves this object by the fact that the method of the invention comprises the following steps:
Thus, in the invention, the boring tube is detached and left in the borehole in order to constitute the reinforcing element of the reinforced structure.
It can thus be understood that in the invention the boring tube serves both as boring means, as a guide duct for pumping the sealing grout in the borehole, and as the reinforcing element for the reinforced structure. The distal end of the boring tube preferably presents at least one perforation, and the boring fluid is injected into the boring tube so that the boring tube also acts as a guide duct for pumping the boring fluid in the borehole.
Thus, by means of the invention, the steps of injecting boring fluid and sealing grout into the borehole, and of introducing the reinforcing element are performed more quickly than in the traditional method.
In addition, making the borehole while causing the boring tube and thus the boring member to vibrate serves to facilitate penetration of the boring tool into the ground, thereby further improving the speed at which the reinforced structure is installed in the ground. During boring, the boring tube is preferably also rotated so as to change the positions of cutting teeth arranged at the distal end of the boring tube.
Advantageously, the vibration frequency applied to the boring tube lies in the range 50 hertz (Hz) to 200 Hz.
The diameter of the cutter member is preferably greater than the diameter of the boring tube, thereby making it possible to ensure that the sealing grout coats the boring tube correctly.
The term “distal” end is used to mean the end of the boring tube that is remote from the means for driving the boring tube in rotation. The term “proximal” end is thus used for the other end, which is situated close to the means for driving the boring tube in rotation.
In order to enable the boring fluid and the sealing grout to flow in the borehole, it can be understood that the distal end of the boring tube presents at least one perforation. In preferred manner, the boring member has an annular periphery provided with cutter teeth and preferably carries a diametral cutter element. The term “cutter teeth” is used to mean boring tools in general, such as tungsten carbide pellets, buttons, spikes, etc. The diametral cutter element serves to increase the area of interaction between the cutter element and the terrain, so that the cutter element can perform boring over an area that is greater than the area of the cutter member. Consequently, the efficiency of the method is further increased.
The diametral cutter element may be understood as meaning that the cutter tool is a “full face” tool having at least one perforation.
Advantageously, boring fluid is injected into the boring tube while the borehole is being made.
In preferred manner, the sealing grout is used as boring fluid.
In a variant, additional reinforcing equipment is also introduced into the boring tool, e.g. a metal bar. This additional reinforcing equipment may for example be introduced after the boring step and immediately prior to injecting the sealing grout.
Advantageously, while injecting the sealing grout, the boring tube is caused to vibrate, preferably without being driven in rotation. The term “sealing grout” is used to mean any sealing substance based on cement, slurry, or any other binder.
This vibration serves to facilitate the flow of the sealing grout in the borehole, thereby having the consequence of further improving the speed at which the method of the invention is executed and also the quality of the sealing of the reinforcement in the ground.
In preferred manner, centering means are fastened to the boring tube in order to ensure that the reinforcing element is substantially centered in the borehole while the sealing grout is being injected, so as to guarantee that the reinforcing element is well coated by the sealing grout.
It can be understood that these centering means together with the cutter member serve to guarantee that the reinforcing element is properly coated in sealing grout.
In a variant, the direction of the borehole is inclined relative to a vertical direction.
The method makes it possible in particular to make horizontal boreholes.
Preferably, the direction of the borehole is inclined relative to the vertical direction by an angle that is strictly greater than 90°. An advantage is to be able to make rising reinforced structures.
In an advantageous implementation, a target vibration frequency is calculated and the boring tube is caused to vibrate at said target vibration frequency while making the borehole.
This target vibration frequency, which is applied to the boring tube, is selected in optimum manner in order to facilitate the boring operation, specifically in ground that is particularly hard. In general, the calculation is performed on the basis of a model of perforation phenomena.
Advantageously, the calculation makes use of the length of the boring tube. Preferably, the target vibration frequency is a function of the length of the boring tube, while also being limited by a predetermined maximum frequency value, which preferably corresponds to the maximum frequency that can be developed by the means for causing the boring tube to vibrate. This predetermined maximum frequency value preferably lies in the range 100 Hz to 160 Hz. Also preferably, the calculation makes use of a constant value corresponding to the propagation speed of compression waves in the boring tube, where this speed depends on the material from which the boring tube is made.
In preferred but non-essential manner, the reference target vibration frequency is equal to:
The inventors have found that this formula makes it possible to obtain an optimum target vibration frequency that significantly increases the effectiveness of the boring operation.
This calculation is performed by a computer having appropriate calculation means.
In order to make deep boreholes, the length of the boring tube is increased while the borehole is being made. For this purpose, use is made of tube portions that are fastened together end to end during boring so as to increase the length of the borehole. Consequently, in the meaning of the invention, the term “boring tube” is used to cover equally well a single boring tube or a plurality of tubular elements fastened end to end, e.g. by screw fastening.
In advantageous manner, the target vibration frequency is recalculated each time the length of the boring tube is increased.
An advantage is to perform boring with optimum efficiency over the entire length of the borehole.
In a first implementation, the method of the invention is performed to make a micropile.
In a second implementation, the method of the invention is performed to make an umbrella vault.
The invention can be better understood on reading the following description of embodiments of the invention given as non-limiting examples and with reference to the accompanying drawings, in which:
With reference to
In accordance with the method of the invention, a boring tool 10 is provided that comprises a boring tube 12 made up of a plurality of tubular elements 12a, 12b, 12c, . . . . These tubular elements are fastened together end to end so as to constitute the boring tube 12.
It can thus be understood that the length L of the boring tube 12 varies while making the borehole. More particularly, while making the borehole, as the boring tool penetrates further into the ground, new tubular elements are added to those already inserted into the ground in order to increase the length L of the boring tube 12.
The boring tube 12 has a distal end 14. In the example of
In this example, the cutter member 16 is a fitting that is mounted on the distal end 14 of the boring tube 12.
The boring tube 12 also has a proximal end 17 that is connected in this example to means 18 for driving the boring tube 12 in rotation and to means 20 for causing the boring tube 12 to vibrate.
In this example, the means 18 for driving the boring tube 12 in rotation comprise a hydraulic motor.
The means 20 for causing the boring tube to vibrate, specifically a vibration generator 20, serve to generate compression waves that are transmitted along the boring tube 12 from the proximal end 17 towards the distal end 14.
In
In accordance with the invention, a borehole F is made in the ground S using the boring tool 10 by causing the boring tube to rotate about the vertical axis A by using the rotary drive means 18 and by causing it to vibrate by using the means 20 for causing the boring tube 12 to vibrate.
While making the borehole, a boring fluid is injected into the boring tube so as to evacuate the debris excavated by the cutter member 16. As can be seen in
Thereafter, as shown in
These centering means 30 serve in particular to center the boring tube 12 at the foot of the borehole F while the sealing grout is being injected so as to ensure that the boring tube is coated by the sealing grout. The centering means 30 are thus arranged to avoid the wall of the boring tube coming into contact with the terrain. In this example, the centering means 30 are in the form of fins that are fastened to the outside wall of the boring tube 12. The sealing grout C flows through the perforations 26 so that the boring tube 12 becomes embedded in the sealing grout C.
In this example, while the sealing grout C is being injected, the boring tube 12 is caused to vibrate without being driven in rotation, thereby enhancing the flow of the sealing grout in the borehole F.
After the sealing grout has been injected, the boring tube is adjusted to its final position, which is generally a little higher than the bored depth, and it is held in this position, with the boring tube 12 being detached from the boring tool 10. In other words, the boring tube 12 is left in the borehole filled with the sealing grout.
In this example, before the sealing grout has set completely, fastener equipment 40, e.g. a short metal bar, is added to the top end of the borehole F, thereby obtaining a reinforced structure in the form of a micropile M having a reinforcing element that is constituted by the boring tool 12.
In a particularly advantageous aspect of the invention, while making the boreholes F and F′ as described above, it is desired to optimize the vibration frequency so as to maximize the boring energy that is transmitted by the boring tube 12. For this purpose, a target vibration frequency is calculated for application to the boring tube 12 by the vibration generator.
The boring tube 12 is thus caused to vibrate at the target vibration frequency while making the various boreholes F, F′. It can thus be understood that this target vibration frequency is a vibration frequency that is applied to the boring tube. Specifically, the vibration comprises compression waves that travel along the boring tube defining nodes and antinodes. These vibration waves cause the boring tube 12 to enter into resonance, or at least they are at a frequency close to its resonant frequency, thereby maximizing energy on the cutter member 16, with the effect of significantly increasing the efficiency of boring, and thus the overall efficiency of the method of the invention.
Calculating the target vibration frequency begins with a step S100 during which the length L of the boring tube 12 is input manually or is determined automatically. It is assumed in this example that the boring tube is set into vibration over its entire length.
Thereafter, on the basis of this length, the target vibration frequency is calculated during a step S102 on the basis of the length L of the boring tube, and of the propagation speed of the compression wave in the boring tube 12, which in this example is made of steel.
Also preferably, the calculation makes use of a constant value that corresponds to the propagation speed of compression waves in the boring tube, which speed depends on the material from which the boring tube is made.
In accordance with the invention, insofar as the length of the boring tube 12 increases while the borehole is being made because successive tubular elements 12a, 12b, . . . , are added, the target vibration frequency is recalculated each time the length of the boring tube is increased. This makes it possible to conserve an optimum vibration frequency throughout the duration of boring.
The target vibration frequency calculated in this way is then displayed as a suggestion to the operator. In another implementation it may also be set as a setpoint to the vibration generator 20 during a step S104.
In a manner that is preferred but not essential, the reference target frequency is equal to:
In the example below, V is equal to 5000 meters per second (m/s), and Fmax is equal to 130 Hz.
L, the length of the borehole, is equal to the sum of the lengths of the tubular elements 12a, 12b, 12c, . . . . In this example, the tubular elements have the same unit length, namely a length of 3 m.
The following table of results is obtained:
Number | Date | Country | Kind |
---|---|---|---|
12 59136 | Sep 2012 | FR | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/FR2013/052276 | 9/26/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/049278 | 4/3/2014 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2403643 | Dresser | Jul 1946 | A |
3557875 | Solum | Jan 1971 | A |
4732510 | Louis | Mar 1988 | A |
4832535 | Crambes | May 1989 | A |
7270182 | Johnson, Jr. | Sep 2007 | B2 |
20030221870 | Johnson, Jr. | Dec 2003 | A1 |
20040007387 | Bar-Cohen | Jan 2004 | A1 |
20040115011 | Fox | Jun 2004 | A1 |
20040120771 | Vinegar | Jun 2004 | A1 |
20040247397 | Fox | Dec 2004 | A1 |
20070031195 | Canteri | Feb 2007 | A1 |
20070286687 | Melegari | Dec 2007 | A1 |
20100040419 | Roussy | Feb 2010 | A1 |
20140369766 | Denker | Dec 2014 | A1 |
20150225941 | Viargues | Aug 2015 | A1 |
20160010305 | Barrett | Jan 2016 | A1 |
Number | Date | Country |
---|---|---|
2246482 | Nov 2010 | EP |
2502208 | Sep 1982 | FR |
2995917 | Mar 2014 | FR |
101489387 | Feb 2015 | KR |
Number | Date | Country | |
---|---|---|---|
20150225941 A1 | Aug 2015 | US |