ES2665914A1 - MACHINE AND METHOD FOR THE PROPOSPTION AND DEEP SIMULTANEOUS AND OPTIMAL CONSTRUCTION OF CONSTRUCTIONS THROUGH THE MONITORED AUTOHINK OF STEEL BARS (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Machine and method for the simultaneous and optimal realization of geotechnical study and deep foundations of any construction by means of the monitored autohinch of steel bars. It is based on the monitoring by sensors (accelerometers and extensometers) of a high resistance thin bar and its driving through powerful impulses of "hanging" impact cylinders activated in it pneumatically/hydraulically/electrically and running in parallel, synchronously and automatically. Thus, with the same technique, the prospection, the calculation of the actual admissible load, the foundation by micropile and the final load test are carried out, all automatically, simultaneously and in a single operation. The final result is an optimal deep foundations system because, in addition to being the safest (it relies on consolidated levels of existence confirmed at each point, it has no uncertainties when performing an initial resistance test and a final load check at each point.) is the fastest and most efficient (high productivity, detects the depth of maximum performance). (Machine-translation by Google Translate, not legally binding)

Description

Machine and method for simultaneous and optimal deep foundations and prospecting of constructions by means of the self-locking of steel bars.

1.1. FIELD OF THE INVENTION

The present invention relates to the realization of geotechnical prospecting of any construction and its deep foundation, being carried out simultaneously and optimally thanks to a self-sharpening bar machine and an instrument for measuring its efficiency and permissible load.

1.2. BACKGROUND OF THE INVENTION The process of foundations deep in areas with soft (clays, silt, submerged sands, etc.) or evolutionary (poured landfills, expansive clays, etc.) is a centennial, known and widespread solution. However, analyzing their different types (Piles, Micropiles, Screens) and execution techniques (drilled, drilled, muddy, driven, etc.) all have the same defects and have not come to be solved in all these years:

one.

Economically inaccessible: It is the most expensive foundation system.

2.

Accessibility problems: The machinery needed is specific, large and spectacular, forcing the builder to spend on generating excellent access prior to the works.

3.

Shortage of supply: The machinery is expensive and its handling complicated, being very few companies that have the economic resources to invest in it and train / maintain their machinists, hindering competitiveness and market supply.

Four.

Straw Productivity: They require the coordination of abundant human resources and bulky materials for one or more of the subprocesses that make up its procedure of realization (transport of machinery and accessories, drilling, concreting, pumping, sludge pool, mounting of ferralla, etc. ).

5.

Operational problems: The machinery must have specific displacement elements within the work (caterpillars, 4x4 traction, special wheels, etc.) through the quagmire or softened soil that causes all the movement of machinery around it, feeding back the higher cost of machinery and its low productivity (points 3 and 4).

6.

Low permissible load due to uncertainty of the Calculation: The correlation between the resistance values obtained from the geotechnical study and the real ones with which the pile will work is very complex, which requires the use of very high safety factors (F = 36) in the calculation and sizing.

7.

Low permissible load due to Model uncertainty: The geotechnical survey carried out is always insufficient between the variability and invisibility of the deep support ground (paleorelieves, reorientation of strata, inclined strata, lack of unaltered samples, etc.), further feeding back the need for High safety factors as in point 6.

8.

In the case of driven piles, in order to avoid the loss of impact energy for penetration through buckling damping, you need a lot of impact energy (large masses) and high stiffness piles (large, high section, either concrete or metal tube base).

9.

Increase in seismic structure: In the face of an earthquake, the deep foundation is safer than the superficial one (it reduces the seismic response and avoids, among other phenomena, liquefaction pathologies), but more expensive.

It should be noted that, by comparison and in our opinion, the concrete technique of driven piles (concrete or metal pipes) is the least bad, since it is less affected by points 4, 6 and 7. This illuminated us towards the present invention.

On the other hand, the two best known and most effective geotechnical prospecting techniques on the market are, without a doubt, the probing and the dynamic penetrometer (DP or dynamic probing). Of all the different types of probes (rotation, rotary percussion, boreholes) and penetrometers (DPL, DPM, DPH, DPSH), it is the Rotation Probe and the DPM, DPH and DPSH (hereinafter, DP) the most used and effective by dig deeper into the survey and by its easy correlation between its striking values ("N30" = No. of strokes / 3D cm. of the well-known Standard penetration testSPT in Probe and the "N2o" = No. of strokes / 20 cm. of the DP) . Even so, both have defects that have not been solved during all these years:

one.

The machinery is expensive.

2.

They require specific machinery, usually large and spectacular, forcing trucks or large vans to be transported.

3.

Little offer (expensive and complicated handling machinery).

Four.

Productivity is low, since its operation is through:

to.

Probing: slow drilling, cutting the ground without thrust and almost without water.

b.

DP: Slow driving down a metal bar introduced meter by meter by hitting the head of a heavy mass in free fall from high altitude.

5.

The machinery must have specific displacement elements within the work (tracks, 4x4 traction, special wheels, etc.).

6.

The recognition of the materials in the surveys and the samples obtained for their lithological and geomechanical classification is difficult and always altered to a greater or lesser extent by the use of more or less abundant water during drilling, increasing the uncertainty of the Model.

7.

None of the prospecting techniques support the calculation of the allowable load in real time.

8.

In the case of PD, the presence of cemented or bowling levels prevents the progress of the trial, being often aborted for what is called a "false rejection" (N2o> 100 obtained sharply despite the tendency was a low N2o).

9.

All the perforations and penetrations made in the Geotechnical Study do not have any use afterwards for the foundation, resulting in a necessary activity for the project, but not very efficient for the work from an overall view.

Well, the present invention arises to provide a System that cancels all these problematic, in addition to being very efficient when performing a very broad survey of the

land at the same time as its foundation. It is based on the driving of a high resistance bar by means of powerful pneumatic impulses generated by a set of impact cylinders "hung" on it, running in parallel, synchronously and automatically. Thus, with the same technique, prospecting, calculation of allowable load and its foundation are performed automatically and simultaneously.

In any case, if only the geotechnical survey is desired, with the same technique and only by varying the impact energy, we obtain the standardized DP tests or the fastest and most efficient surveys on the market.

The final result is an optimal deep foundation system because, in addition to being the safest (it is based on consolidated levels of confirmed existence at each point, it lacks uncertainties when performing an initial resistance test and a final load test at each point ) is the fastest and most efficient (high productivity, detects the depth of maximum performance).

In addition to its use as a foundation and geotechnical prospecting system, it can be applied for hydrogeological prospecting, drilling for water probes, electrical probes, earthing, horizontal pipe drilling and any other utility that involves the introduction into any type of terrain of a solid bar or a hollow tube.

There are some references with certain similarities. As a survey conducted with continuous recovery of unchanged control by introduction of the sample inside a hollow tube, the closest references to this invention are the patent ES-0316190, where the energy necessary for the elevation of the mass that, when Release it, hit the tube to be driven, it comes from a cylinder of compressed air. Obviously our system is much more efficient when using the kinetic energy and not the potential, forcing to transport a heavy club, our system is repetitive automatically and with high frequency and in no case includes a continuous monitoring of the admissible load.

As a driven metal micropile with continuous monitoring of the permissible load at each point, the closest references to this invention are the patent RU-2556755, where a pile is first made, then a static penetrometer at that same point and in all future positions pile and the allowable load is calculated; Finally, after 5-35 days a static load test is carried out on said pile to determine the permissible load. By correlation, where there is the same model as the first pile, the same permissible load will be expected and the rest will be extrapolated. Obviously, our system is much more efficient because I perform foundations and tests to know its admissible load at the same time and in a single operation. Another reference is the ES-1078907-U patent, where the static metal pipe hinges by means of a hydraulic jack, taking advantage of its anchoring in slabs and, therefore, limited to overhangs. Obviously, our system is more efficient because it can be used in new construction (most frequently), because it does not need a complex process of anchoring the machine and because it has no load limitations, because when proceeding the anchor reaction requires that only low loads can be applied to each micropile.

1.3. DETAILED DESCRIPTION OF THE INVENTION

The present invention is a comprehensive and simultaneous system of standardized geotechnical prospecting (ENV 1997-3 Eurocode 7, ASTM D3740 YASTM D4945) and optimal foundation applicable to any type of construction (new or overhanging an existing one) based on the self-sharpening of steel with a self-supporting contraption and monitoring of its permissible load.

This invention, the simultaneous and optimal construction and foundations system of constructions, is characterized by its efficiency (with a small investment in machinery and an adjusted expense for being made with a single person, with little training, and in a few hours a foundation is obtained of maximum performance) and efficiency (generates an optimal foundation without uncertainties, for any bearing capacity and in half the time) with respect to a conventional foundation on ground. This allows to demonstrate that it is the foundation on safer and more productive ground of the existing ones, usually surpassing even the conventional direct foundation.

Broadly speaking, it consists of a machine for self-tapping of tubes using impact cylinders, replaceable as we will see later by a hammer hammer on a backhoe with a special wheel, and a dynamic load analyzer, which instantly calculates the bearing capacity of the pile and warns of the maximum performance length ('Structural top of the pile = Permissible ground load').

More specifically, it consists of the following elements:

one.

Pile bar: Solid or hollow steel bar, with different diameters (always less than 300 mm.) And resistance (structural stop), split lengthwise or not.

2.

Tip: Steel / conical cast iron tip, blind or not, of different diameters.

3.

Set of impact cylinders (pneumatic / hydraulic / electric): Impact cylinders of different diameters and impact energies.

Four.

Cylinder block with hollow threaded sleeve on its axis of different diameters, rotation motor (pneumatic / hydraulic / electric, manual or automatic depending on its distance sensor) and ball bearing between them. The sleeve is sensorized (pack of Accelerometers, Extensometers and Ultrasound emitter / receiver).

5.

Portable guide-tripod with receiver of the block distance sensor and ring with double rotating opening bushing.

6.

Pneumatic / hydraulic / electric motor with air / oil tank.

7.

Pneumatic / hydraulic / electric cylinder with hollow plunger and double acting. For use only during Prospecting.

8.

Pneumatic / hydraulic pump / electric generator. For use only during Prospecting.

9.

Pressure gauge-regulator with solenoid valve.

10.

Suffering sensor: For use with conventional hydraulic hammer mounted on backhoe as an impact source. It is triangular and bi-cylindrical adjustable to different hammer hammer pikes. It includes a set of removable sensors consisting of 2 Accelerometers, 2 Extensometers and may include (or not) Ultrasound emitter / receiver.

eleven.

Dynamic Load Analyzer: Electronic recorder and analyzer that can indicate all or only some physical parameters (GPS Location, Depth, Hit / Reject, etc.) and all or only some of the allowable load calculations (Snapshot: following dynamic driving formulas more admitted by the scientific community such as the Dutch, Hiley, etc. and / or a correlation

Energy / Rejection / Permissible load prepared by the inventor. Corrected, following the High Deformation Dynamic Testing regulations such as European and American EC 7, ASTM 04945, etc. calculating it according to the Case method of the University of Ohio and / or according to the digital analysis of the striking wave).

12.

Anchor plates and nuts.

13.

Concrete / metal beam enclosure: Set of longitudinal, transverse reinforcements and cage-shaped fences to which the bars are connected by plates and screws and subsequently concreted. It is small in size thanks to the small section of the pile. It can also be entirely metallic, using horizontal beams with double UPN.

The basis of its simplicity and functionality is the use of the pile itself and its thread, as well as its monitoring. While the Bar is introduced thanks to the impact kinetically generated by the Block of cylinders that are "hung" from it, the Spinning Motor causes it to ascend rotating on itself (its distance sensor activates it when it detects that it separates of the Guide-tripod located above it) keeping the Block and the sensors at the same height as the operator, facilitating their monitoring.

Excel and solve the defects of the construction of Piles:

one.

Economically accessible: The system is now very cheap.

2.

Great accessibility: The machinery is now light and removable when the pile itself is used as a striking guide column and the striking system is dismantled, allowing access to any place due to its possibilities of transfer separately from each of the constituent elements (pile + beating system + motor-compressor + recorder). Even the use of specific machinery can be avoided and only the hammer hammer of a backhoe excavator can be used as a driving system, as long as a custom jaw and a Dynamic Load Analyzer are available.

3.

It facilitates the Offer: Being the cheap machinery and its simple handling, it increases the competitiveness and the market offer.

Four.

High Productivity and Quality: It requires very few human and material resources for all processes, with a simple and economical quality control.

5.

High operability: It does not require almost machinery and the one it has can be moved manually.

6.

Calculation and immediate sizing: Rapid pre-sizing and optimal sizing by instantaneous determination of allowable load estimated by dynamic load test thanks to the Analyzer, being able to optimize it after a few hours or days with subsequent corrections.

7.

Increase the permissible load: A survey on each pile, generating tens, even hundreds in each construction instead of 3 or 4 as usual, and with direct measurement of its bearing capacity, allowing to reduce the Safety Factor (F = 3 -7 1.5 -2) and, therefore, to be able to double the allowable load with respect to conventional techniques.

8.

Maximum use of impact energy (minimum dissipation): Despite the small section of the bar, buckling is canceled thanks to striking very close to the ground and the high structural section of the bar (solid or thick tube).

9.

Deep foundation at the surface price: The efficiency and productivity obtained allows the foundation to be cheaper to make it even more competitive than conventional shoe foundation.

Resolve all defects of DP penetrometers and Probes:

one.

Economically accessible: The system is now very cheap.

2.

Great accessibility: The machinery is now light and removable. Even the use of specific machinery can be avoided and only the hammer hammer of a backhoe excavator can be used as a driving system, as long as the Dynamic Load Analyzer is available.

3.

Facilitate the Offer: The machinery is now cheap and very simple.

Four.

Productivity is high and quality:

to. Probing: drilling by generating a continuous unchanged sample and a continuous SPT, which increases the quality of this technique well above the existing ones.

5 b. DP: high speed by kinetic control of driving energy.

5.

High operability

6.

Increases the permissible load: The truthful and analytical recognition of materials in

10 the surveys are already a reality, reducing the uncertainty of the model and, therefore, allowing to reduce the calculation safety factor.

7. First prospecting technique that calculates and records the permissible load in real time.

lS

8. It increases the depth of the DP test and prevents "false rejection" (because it is possible to increase the driving energy, the high dynamic loads introduced, if it fails to cross that level it is because it is really very competent).

20 9. Efficiency: All perforations of the Geotechnical Study are used for the foundation.

Therefore, the invention encompasses 3 Products and 9 Systems / techniques:

P1) Self-supporting kinetic bar self-tapping machine, adding small accessories

25 according to its purpose: a) for optimal Foundation (adding Analyzer). b) for DP-kinetic dynamic penetration (adding hollow plunger cylinder and

Analyzer). c) for Probe drilling (adding sectioned tube, hollow plunger cylinder and

Analyzer).

P2) Dynamic Load Analyzer: Set of Recorder-analyzer and Sensors (accelerometers and extensometers) for determination of Hit / Depth / Permissible load.

P3) Sensorized Gadget-Suffridera (accelerometers and extensometers) for bar driving

adaptable to any hammer mounted on backhoe loader (or other

similar mechanism).

S 1) Efficient deep foundation system using driven micropiles with self-supporting machinery and optimum length warning.

S2) Efficient geotechnical Prospecting System using DP penetrometers with self-supporting machinery and permissible load register.

S3) Efficient geotechnical Prospecting System by means of well drilling with self-ported machinery and permissible load register.

S4) Foundation / Prospecting System by hammer hammer on backhoe with load analysis.

S5) Efficient deep foundation system using driven micropiles with external hammer hammer and optimum length warning.

S6) Efficient geotechnical Prospecting System using DP penetrometers with external hammer and permissible load register.

S7) Efficient geotechnical Prospecting System by means of Drilled soundings with external hammer hammer and admissible load register.

S8) Optimal Building Foundation System by merging the foundation system and prospecting systems simultaneously and with self-supporting machinery.

S9) Optimal Building Foundation System by merging the foundation and prospecting systems simultaneously and with an external hammer hammer.

Used as a foundation, this technique is the most competitive of all existing deep foundations, competing even with direct ground foundations.

Used as a survey, either as a Probe or as a dynamic Penetrometer, this technique is the most competitive and efficient of those existing on the ground, since it directly and instantly provides the normalized N30 values and the permissible Load for any type of foundation (deep or superficial).

1.4. DESCRIPTION OF A PREFERRED EMBODIMENT

An embodiment of the invention as a Foundation element comprised the following steps:

to.

Data collection: Plans of the structure and loads transmitted to the foundation were collected.

b.

Cabinet sizing: It was determined:

or No. piles needed.

o Geometry (bar and tip section, length)

o Optimal rejection to demand ("R2o" or "R10") according to different driving formulas (Dutch, Hiley, Janbu, etc).

o Ideal hit energy and, therefore, choice of the appropriate block.

C.

We carry out the installation and assembly of the driving machine.

o The cylinder block was placed on the point to be drilled.

o The Cylinder Assembly was mounted regulating the length of travel of the piston at which it generates the maximum impact energy

o The appropriate sleeve was placed in the Block to the bars to be nailed according to the previous sizing.

o The Guide-tripod was placed and the bar was introduced by it.

o The tip was placed on the ground and the bar was threaded into the sleeve until both are connected.

o The engine was started and the block was raised up to half the height of the guide tripod by manually operating the rotation motor. From this moment it is automatically passed (the rotation motor will be activated, it will raise the Block when they move away more than that distance).

o Cylinders were activated at the appropriate pressure (6 bar by default) and the driver started. You just had to splice bars.

d.

Other bars were hammering the hammer hammer, replacing step c) with the placement of sensorized Suffridera under the spike.

and.

The first Control Piles (at least 5% of the total) were carried out in places where a different terrain model was foreseen. Correction-1 of the optimal rejection was made thanks to the driving control by means of the Dynamic Load Analyzer to determine when to stop each pile (its optimum length).

F.

After several days Correction-2 was carried out using the Wave Equation method (differentiates bearing capacity by tip and by shaft).

g.

Results Report with the position, geometry, length and permissible load of each pile was written.

h.

Once all its piles were driven, the Encepado was performed on each structural support (footing or wall) by placing the assembly cage, plates, screws and concreting.

For the realization of the invention as a dynamic-kinetic penetrometer, the same procedure as for the foundation was followed, with the caveats:

•

The introduced bars are 32mm in diameter. (max. 6 kg / m).

•

The tip is bi-conical at 90 ° in the lower cone and 11 ° in the upper spindle, with a diameter of 3450 mm. and intermediate cylinder length 35-50 mm.

•

The length of the piston stroke of the impact cylinders is regulated (failing that, the pump pressure is reduced to that determined for the installed cylinders) so that the sums of cylinder impacts do not exceed the specific energy per standardized stroke (238 kJ / m2).

•

The bars and the tip are recoverable and extracted by hollow piston cylinder.

•

The Results Report includes for each DP:

o GPS position

° Graphs of several Stroke / Depth (NTRAMO, N30, ...) and Permissible loads / Depth (piles, footing, slabs) and Final length.

For the realization of the invention as a percussion probe, the same procedure as for the foundation was followed, with the caveats:

• The bars have the characteristic of being cut longitudinally and the tip is

5 open, which allows it to be filled only when driving it generating a continuous unchanged sample. Its content can be extracted by sections (when the stability of the walls allows it) to ensure the absence of seals.

• The bars are recoverable and extracted by hollow piston cylinder.

• The Results Report includes for each Survey:

o GPS position

° Graphs of several Stroke / Depth (NTRAMO, N3Q, ...) and Permissible loads / Depth (piles, footing, slabs) and Final length.

Claims (16)

one.

Apparatus for driving beams, bars or tubes (number [1] in drawing) by striking, characterized in that, additionally, it uses the kinetic energy generated by the synchronous drive of a connected set of impact cylinders [2] and obtained from a motor (electric / pneumatic / hydraulic).

2.

Apparatus according to claim 1 which, in addition, allows efficient self-inflation of bars / tubes. When using only threaded bars / tubes, the cylindrical block [3] that contains the cylinders includes on its axis a through sleeve that is threaded to the bar [4] itself, allowing it to be located not on it, as historically, but " hung "from it at the desired height. This prevents the energy damping of the bar by buckling in the air, as we place the block at low ground height. It is complemented with a Guide-tripod ring [5] located above the machine to maintain its verticality.

3.

Apparatus according to claim 1 and 2 which, additionally, allows automatic operation, thanks to the autogyro device [6] and self-locking of the Block in the bar that supports it. It includes a distance sensor synchronized with a receiver in the Tripod Guide that activates the device and allows it to maintain its relative distance and, therefore, at the same height of the ground despite the bar being driven.

Four.

Apparatus according to claim 1, 2 and 3 which, additionally, allows its operation as a portable micropile machine for deep construction foundations thanks to the fact that it allows to apply a high specific driving power, similar or even proportionally superior to that they contribute the great piloting machines.

5.

Apparatus according to claim 1, 2 and 3 which, additionally, allows its operation as a portable dynamic penetrometer for geotechnical prospecting complying with at least European and American geotechnical testing standards (Eurocode 7, ASTM 03740) in any of the OP types (SPT , OPM, OPH, OPSH). It allows to regulate the energy of the blow to obtain the standard of the test (lower than that used as a foundation technique) or to correct the penetration values in the recorder to pass them to standardized standard values. Alternatively, the Sufridera sensorized-Hammer hammer assembly can be used as a driving mechanism. Subsequently, the bar (or not) is removed by means of a hollow piston hydraulic cylinder.

6.

Apparatus according to claim 1, 2 and 3 which, additionally, allows its operation as a Probe with continuous recovery of portable witness for geotechnical prospecting thanks to introducing a longitudinally sectioned tube with open tip into the ground, which allows its self-filling with He drives her. Subsequently, the tube is removed using a hollow plunger hydraulic cylinder.

7.

Electronic dynamic pile analyzer device (7) complying with at least European and American High Deformation Dynamic Testing regulations (EC 7, ASTM 04945) to obtain the load capacity of the pile, characterized in that it additionally calculates in real time and shape the permissible load continues with depth by different dynamic methods and warns upon obtaining the optimum length (permissible ground load = structural pile stop). It is complemented with a sensorized sleeve [8].

8.

Device according to claim 7 which, additionally, corrects the penetration values obtained "N" by dynamic and energetic criteria to obtain the normalized equivalent values (N2o, N30 ..) of any of the DP and Probe types, calculating so Continuously and instantly the permissible load for all types of direct foundation (footing, well, slab) and deep bar driving. This significantly speeds up the calculation of the structure and, therefore, the construction project by being able to instantly send the eligible load for any foundation to the designer.

9.

Gadget for hitting elements of beams, bars or pipes for building foundations by means of an external hammer mounted (or not) mounted on a backhoe, characterized in that, additionally, it connects a hammer and a bar by means of an adjustable sensorized hole [9] to any spike of the hammer and at any height of the bar and that allows to monitor the driver.

10.

Apparatus according to claim 7, 8 and 9 which, additionally, allows its operation for geotechnical prospecting as a Normalized Dynamic Penetrometer (DP), thanks to the Empirical Correction Factor established on the basis of the driving energy and weight of the bar, and as Probe with continuous witness recovery.

eleven.

A method that includes the impact of beating elements of beams, bars or pipes for building foundations, characterized in that, additionally, it is a portable equipment composed of impact cylinders and that keeps continuously monitored

it drives it by electronic devices that instantly indicate the permissible head load of the element and warns when we should stop the drive when obtaining its optimum length. Previously, several input data is entered into the device, including the bar section.

12.

Method comprising geotechnical prospecting type normalized dynamic penetrometer (OP) characterized in that, additionally, it is a portable device and allows to increase the driving energy (dynamic or static) and the striking frequency in order to cross hard levels or boluses that prevent its progress, recovering its standardized energy and frequency once crossed.

13.

Method that includes the geotechnical prospecting type survey with control recovery while a dynamic SPT type penetrometer, characterized in that, additionally, it is a portable device and is carried out by means of the driving (dynamic or static) of longitudinally sectioned tubes that allow its self-filling With the driver. The result is, after extraction of the tube by means of a hollow piston hydraulic cylinder, obtaining a continuous and unaltered soil sample. It also allows to increase the energy of the driver with the aim of deepening the investigation and / or crossing hard / bowling levels.

14.

A method that includes tapping of beams, bars or pipes for building foundations by means of commercial hammer hammer mounted or not mounted on backhoe, characterized in that, additionally, it is connected to the element to be driven by sensorized Suffridera adjustable to the spike and, with the appropriate analyzer, it allows to determine continuously the load capacity in head of the element, notifying us of its optimal length. Previously, several input data is entered into the device, including the bar section.

fifteen.

Method of calculation of the bearing capacity of a bar / pile by dynamic load test, whether or not following international regulations (EC 7, ASTM 04945, etc.), which additionally obtains the permissible load of a micropile continuously and in real time during its approach following a new technique based on the Energy-Rejection correlation developed by the inventor (which includes the contribution of the upper levels) and compares it with those obtained by a selection of formulas of dynamic load capacity (those considered more coincident with static load capacity), finally choosing the most suitable one, all without waiting for days like

It usually occurs. It also calculates in real time the bearing capacity against buckling, comparing it with the bearing capacity against sinking and limiting the final value to the lower of the two. It may or may not be optimized to the permissible load corrected by rehinca after one or several days and its recalculation with digital wave analysis 5 with the Analyzer and software revindicated here. 16. Building Foundation System that additionally fuses the Apparatus, Gadgets, Devices and Methods described in claims 1 to 15, providing an efficient, effective and rapid foundation solution.