NL2005943A - METHOD FOR INSTALLING A GROUND-LOCKING SCREW DRILL POLE - Google Patents

Abstract

Method for the installation of a rotary soil displacing pile in a subsoil (1) by means of an installation assembly (2) and a soil displacing screw drill (3), wherein the installation assembly comprises a base frame (20), a leader (21) placed on the base frame, along which a rotary drive (22) equipped at its lower side with a coupling (23) driven by the drive can move and to which the soil displacing screw drill (3) is coupled, wherein the method comprises the following steps; - the transmission of the rotary movement of the coupling on the screw drill, - the penetration of the screw drill with a rotating motion in the subsoil, - the application of concrete in the created space in the subsoil by the screw drill, - the retraction of the screw drill, and - the hardening of the concrete to a rotary soil displacing pile, wherein the method further comprises the step of the measurement or derivation of the net downward force which the pile toe (32) exerts to the subsoil (1) during the rotational penetration of the screw drill (3) into the subsoil, wherein the bearing capacity of the rotary soil displacing pile is determined on the basis of the net downward force.

Description

Method for placing a soil displacing screw drill pile

BACKGROUND OF THE INVENTION

The invention relates to a method for placing a soil displacing screw drill pile in a substrate with the aid of a positioning assembly and a screw drill.

It is known to use a probing device in a method for placing a soil displacing screw drill pile in a subsurface, and to perform one or more measurements with the probing device in the subsurface at a particular construction site, from which the in-situ geo technical characteristics of the substrate. Based on this, a general depth is determined in the subsurface to which the screw bores must be inserted. Subsequently, a hollow steel casing pipe with a closed foot is installed in the substrate. After the application of concrete and any reinforcement in the casing pipe, the casing pipe is withdrawn in order to leave the ground displacing screw drill pile formed from the concrete. The concrete screw bores can then be used to support a structure or as tensile elements to absorb upward forces on structures.

In practice, however, it has been found that, when using this method, in a number of cases the supporting force supplied by the concrete and screw bored piles may, in contrast to the expectation, be insufficient to support the structure.

It is inter alia an object of the invention to provide a method with which the above-mentioned problem is avoided as much as possible, and a method is provided with which properties of a substrate can be reliably determined.

SUMMARY OF THE INVENTION

To this end, the invention provides, from a first aspect, a method for placing a ground displacing screw drill pile in a substrate with the aid of a screw drill and a positioning assembly, the screw drill being provided with a steel casing pipe which is coupled at the bottom to a pole foot, the positioning assembly being provided with a frame, with a broker placed on the frame, along which a drive motor with a coupling placed on the underside thereof and driven by the drive motor can move up and down to which the casing of the screw drill is coupled, wherein the method comprises the following steps; transferring the rotary movement of the coupling to the screw drill, wherein the coupling exerts a pressing force on the screw drill, rotating the screw drill in the ground, the screw drill displacing a soil volume in the ground of at least 70% of the volume that the screw drill occupies in the ground, the installation of concrete in the space occupied by the screw drill in the subsurface, the retraction of the screw drill, and the hardening of the concrete to a ground displacing screw drill pile, the method further taking the step comprises of receiving or diverting the net pressing force exerted by the pole foot on the substrate during the rotation of the screw drill into the ground, the bearing force of the soil displacing screw drill pole being derived on the basis of the net pressing force. The invention is based on the direct relationship between the net pressing force during the turning of the screw drill into the ground and the bearing capacity of the displacing screw drill pile achieved later. By now determining the soil properties according to the invention during the insertion of the screw bores, sufficient information about the properties of the substrate can be obtained to determine the pile point level at which the correct bearing capacity is provided. By determining the geotechnical properties at every location of a soil displacing screw drill pile, a pile with a higher safety level against collapse and with a better knowledge of the elastic behavior during loading can be obtained. For an optimization of the screw bored piles, where the installation time, the amount of materials used and the safety against collapse are concerned, it is important to carry out a sounding preferably at the location of all screw bored piles in order to thereby explore the in-situ conditions. With the method according to the invention, it is possible to carry out an effective sounding for each soil displacing screw drill pile in an effective manner, as it were.

In an automated embodiment, the placement assembly is further provided with a measuring device for determining the load-bearing capacity, wherein the load-bearing capacity of the soil-displacing screw drill pile is carried out with the aid of the measuring device, wherein the measuring device comprises sensors and an information processing unit, wherein the step of determining the bearing capacity of the soil displacing screw drill pile with the aid of the measuring device comprises the following steps; determining measured values with the sensors; supplying the measured values of the sensors to the information processing unit; performing algorithms on the measured values for calculating the bearing capacity of the soil displacing screw drill pile.

In one embodiment thereof, while rotating the screw drill in the ground over the insertion path for several measuring intervals, the steps are performed of determining measured values with the sensors; supplying the measured values of the sensors to the information processing unit; performing algorithms on the measured values for calculating the bearing capacity of the soil displacing screw drill pile. In this way real-time data is available about the future bearing capacity of the soil displacing screw drill pile, so that during the insertion into the soil the moment at which insertion can be stopped can be determined.

In a first embodiment thereof, the screw drill is provided at the location of the pole foot with a first sensor for receiving a net pressure force exerted on the ground by the pole foot, one of the measured values being the net pressure force of the pole foot on the ground .

In a practical embodiment thereof, the first sensor is included between the casing tube and the pole foot. Due to its special position, the first sensor provides data directly on the magnitude of the downward compressive force exerted on the ground by the pole foot during turning into the ground, because this compressive force is equal to the compressive force exerted by the casing on the pole foot.

In an embodiment related to the first sensor, a software program can be loaded into the information processing unit which, when executed, simulates a cone resistance, the algorithms being executed comprising at least one of the following group of algorithms; calculating a cone resistance qc; p; for; n as a measure of the pressure that a cone of a probing device would have exerted if it had been provided at the location of the screw drill in the still untouched surface prior to the application of the screw drill, by dividing the net pressing force Pnet; n by an area A as a measure for the area under the base of the pile, and by multiplying the result thereof by a multiplication factor APj 'as a measure for the ratio between the cone resistance qc; p; for; n and the net pressure force Pnet; n divided by the area A.

The cone resistance can be part of the design and execution procedures according to the applicable building codes and standards, so that the simulated probe can be used as part of the quality control of the design and the installation of the foundation.

In a second embodiment, the placement assembly is provided with a second sensor for receiving a gross pressure force exerted by the coupling on the casing tube, one of the measured values being the gross pressure force of the placement assembly on the threaded drill. The second sensor is located at the coupling that usually does not come into contact with the ground.

In an embodiment related to the second sensor, a software program can be loaded into the information processing unit which, when executed, simulates a cone resistance, the algorithms being executed comprising at least one of the following group of algorithms; calculating a net pressure force Pnet as a measure of the force that the pole foot exerts on the subsurface by reducing the gross pressure force P gross on the screw drill with a cumulative dynamic frictional force Pdyn friction as a measure of the cumulatively built up frictional force between the casing of the screw drill and the substrate, calculating the cumulative dynamic friction force Pdynwrijvcum; ï -> ni, where n is the measurement interval in which is measured, by an effective vertical soil stress δ'ν; η, a coefficient of the horizontal soil pressure Kh; na; n and a tangent of the angle of effective internal friction φ'ηβ, -η with each other, by adding the effective cohesion c'n to the result thereof or instead of this multiplication and sum the wall adhesion fadh, -n, and by multiplying the result thereof by a circumference 0 as a measure of the circumference of the pipe sleeve and by e and length Lintervai as a measure of the always equal measurement interval, and by multiplying the result thereof by a factor Fdyn; n as a measure of the ratio between the dynamic friction between the casing pipe and the substrate and the static friction of the substrate and the summing of the substrate the calculated dynamic friction of the individual intervals passed by the screw drill, the calculation of a cone resistance qc; p; for; n as a measure of the pressure that a cone of a probing device would have exerted if it had been applied at the location of the screw drill in the still untouched surface prior to applying the screw drill, by dividing the net pressing force Pnet, -n by an area A as a measure for the area under the pole foot, and by multiplying the result thereof by a multiplication factor AP; n as measure for the ratio between the cone resistance qc; p; for; n and the net contact force Pnet; n divided by the area A.

In this embodiment, the net pressure is obtained indirectly, namely by correction of the gross pressure. On the basis of this, the cone resistance is again obtained, with which the bearing capacity of the screw drill pile can be calculated. The cone resistance can be part of the design and execution procedures according to the applicable building codes and standards, so that the simulated probing can be used as part of the quality control of the design and the installation of the foundation.

The invention provides, from a second aspect, a placement assembly which is apparently intended and suitable for use in the method according to the invention, which placement assembly comprises a measuring device, wherein the measuring device comprises sensors and an information processing unit, the sensors comprising the information are connected to a data processing unit for supplying measured values thereto, wherein a software program is loaded into the information processing unit which, when executed, simulates a cone resistance from which the bearing capacity of a soil displacing screw drill pile can be determined.

The invention provides, from a third aspect, a measuring device which is apparently intended and suitable for use in the method according to the invention, wherein the measuring device comprises sensors and an information processing unit, wherein the sensors are connected to the information processing unit for supplying measured values, wherein a software program is loaded into the information processing unit which, when executed, simulates a cone resistance, from which the bearing capacity of a soil displacing screw drill pile can be determined.

The aspects and measures described in this description and claims of the application and / or shown in the drawings of this application can, where possible, also be applied separately from each other. Those aspects can be the subject of targeted split-off patent applications. This applies in particular to the measures and aspects that are described per se in the subclaims.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be elucidated on the basis of a number of exemplary embodiments shown in the attached schematic drawings. The following is shown in: figure 1 a view of a subsurface of a construction site with a placement assembly and a screw drill according to the invention thereon, figure 2 a view of a part of the placement assembly according to figure 1, figure 3A a detailed view of a part of the Fig. 3B is a bottom view of the screw drill of Fig. 1, Fig. 4 is a view of a process step in which the screw drill of Fig. 1 has been placed in the substrate by the positioning assembly of Fig. 1, Fig. 5 is a schematic representation of the forces which 1, Fig. 6 is a diagrammatic representation of a structure that is placed on a number of screw bores arranged in the subsurface according to the method according to the invention.

DETAILED DESCRIPTION OF THE DRAWINGS

The invention will be described below with reference to an embodiment.

Figure 1 shows a subsurface 1 of a construction site with a placement assembly 2 thereon and a soil displacing or partially soil displacing screw drill 3 connected to the placement assembly 2, with a possible length of a few meters to approximately twenty meters. In order to be able to build a structure, such as a building, on the subsurface 1, it may be necessary, depending on the bearing capacity of the subsurface, that several screw-bored piles are installed in the subsurface 1. In this example, the substrate 1 comprises a number of soil layers 11-14, such as, for example, peat, clay, silt, sand, gravel and / or a mixture of these materials, with different geotechnical properties per layer 11-14.

The placement assembly 2 comprises a frame 20 and a vertical broker or guide column 21 placed on the frame 20. The placement assembly 2 is provided with a drive motor 22 suspended from the guide column 21 and movable up and down along the guide column 21. At the end of the drive motor 22, the placement assembly 2 is provided with a rotary driven clutch 23.

As shown in Figure 3A, the screw drill 3 comprises a circumferential steel casing pipe 31 with center line S. The screw drill 3 comprises at the bottom of the casing pipe 31 a pole foot 32 for loosening and displacing the substrate 1 under the screw drill 3. On the at the desired depth, the casing tube 31 can be filled with concrete and any reinforcement, whereafter the hollow casing tube 31 is withdrawn and concrete remains in the shaft space created by displacing the substrate 1. In this way a soil displacing screw drill pile 6 formed from the concrete is left behind, three of which are shown in Figure 6 supporting a structure 61. The pole foot 32 then remains behind in the ground 1 as a so-called lost foot.

As shown in Fig. 3B, the pole foot 32 is provided with a bearing surface having the shape of a part of a sphere 33 with a drill comb 34 protruding vertically downwards thereof. The pole foot 32 is provided with a circumferential screw edge 35 along the circumference. 3 is attached to the coupling 23 of the positioning assembly 2 with the top of the casing tube 31 in order to be able to take over the rotation of the coupling 23 in direction M.

As shown in figures 3A and 5, a first sensor 41 is arranged between the casing tube 31 and the pole foot 32, which sensor is adapted to take up the pressure force that the casing tube 31 exerts on the pole foot 32. As shown in figure 1, the positioning assembly is 2 provided with a second sensor 42 which is adapted to take up the compressive force exerted by the positioning assembly 2 on the casing tube 31 via the coupling 23.

As shown in Figure 2, the positioning assembly 2 comprises a measuring device 4 which is connected to the first sensor 41 and the second sensor 42 for recording measurement data thereof. The measuring device 4 is provided with an information processing unit 45 with a software program loaded in the information processing unit 45 which, when executed, processes data from the sensors 41, 42, a data storage unit, in this example an internal hard disk 43, for storing data the processed data and a readout display 44 for graphically displaying the processed data.

Figure 4 shows the situation in which the screw drill 3 as a result of the rotation in direction M and a pressing force of the positioning assembly 2 on the screw drill 3 is arranged via the coupling 23 in direction T up to the base layer 13 in the substrate 1. In this case, the drill comb 34 has loosened material from the substrate 1 under the pole foot 32 and moved it from the center region in line with the screw drill 3 to the outside thereof. During the lowering, the screw drill 3 has occupied the vacated space, which arises when the material is moved in direction B to a columnar area 15 around the screw drill 3 and compacted. The substrate 1 within this columnar region 15 has obtained a higher density as a result of the additional material moved to this region 15 and therefore has higher strength properties than for the provision of the screw drill 3. Typically for the manufacture of screw drill piles the screw drill 3 has displaced below ground level a volume of soil of 70-100% of the volume occupied by the screw drill in the substrate 1. Therefore, hardly any or no relaxation takes place by bringing loosened soil above ground level. In this example, a soil volume of 100% has been displaced because the screw drill 3 has not brought any loosened soil at all above ground level. Therefore, there has been no relaxation in the ground.

For an accurate determination of the maximum permissible load on a soil displacing screw drill pile 6, it has been found to be important that the geotechnical properties of the subsurface 1 within the columnar area 15 in the vicinity of the screw drill 3, which is compacted by applying it, to be determined during the installation of the screw drill 3. From these established geotechnical properties, the bearing capacity of the finally displacing screw drill pile 6 to be formed from concrete can then be determined for each depth level of the pile foot 32 reached.

A number of special symbols and / or indications are used in the following parameter description. At a parameter, n is placed as an index for the different measurement intervals, either measurement steps or the vertical displacement between two measurements within the base layers 11-14. At a parameter a P is placed if the parameter is related to the pressing of the screw drill 3, so that it is forced into the substrate 1. With a parameter, an accent (') is placed as an indication of an effective value of a parameter in the drained substrate 1.

The determination of the load-bearing capacity of the displacing screw-pile 6 in the subsurface 1 is dependent on the following parameters: the gross pressure force P-gross, -n for a measuring interval n as a measure of the force in kilonewton required for a vertical displacement of the screw drill 3 in the substrate 1, the cumulative dynamic friction force Pdynwrijvcum; as a measure of the force in kilonewton, which is necessary to overcome the cumulatively increasing depth of friction between the casing tube 31 of the threaded drill 3 and the substrate 1, the dynamic frictional force being measured in the already passed intervals n, indicated by l -> nl, a net pressing force Pnet; n as a measure of the force in kilonewton, which is necessary to effect a vertical displacement of the pole foot 32 of the screw drill 3 in the substrate 1 for a measuring interval n , a virtual cone resistance qc; p; for; n as a measure of the megapascal pressure for a measuring interval n which would have been applied by a cone of a probing device if it had been provided at the location of the screw drill 3 in the still untouched substrate 1 before applying the screw drill 3, an effective angle of internal friction for a measurement interval n as a measure in degrees of the frictional resistance between the grains in the lower groove nd 1 against collapsing due to a load, prior to the application of the screw drill 3, after an effective angle of internal friction Φ; n for a measuring interval n as a measure in degrees of the frictional resistance between the grains in the substrate 1 against collapse due to a load, after applying the screw drill 3, an empirical relationship Rtg (cp '); n tangent cp' before; tangent (p 'na; n as a measure of the ratio between tangent of the effective angle of internal friction cp'na and tangent of the effective angle of internal friction Φ for; nt effective cohesion c'n for a measurement interval n as a measure for the tension in kilonewton per square meter as a result of the attraction between the constituent cohesive particles of the drained substrate 1, the value of c'n remaining the same regardless of the provision of the screw drill 3, a wall adhesion fadh; n for a measuring interval n as a measure for the adhesion in kilonewton per square meter as a result of the adhesion between the substrate 1 and the screw drill 3, an effective vertical soil stress δ'ν, -η for a measurement interval after Is a measure for the tension in kilonewton per square meter, which exerts the weight of the subsurface 1 on the horizontal surface that the subsurface 1 occupies, an effective horizontal subsurface tension 5'h; n for a measurement interval n as a measure for the tension in kilos -newton per square meter, which exerts the weight of the substrate 1 on the vertical surface occupying the substrate 1, a coefficient of the horizontal soil pressure Kh; na; n, as a measure of the ratio between the effective horizontal soil pressure 5'h, -na; n and the effective vertical ground tension δ'v; n, an empirical relationship Rk; n as a measure of the ratio between the tangents of the angle of internal friction (p'na; n and the coefficient of the horizontal ground pressure

Kh; na; n a factor Fdyn; n for a measurement interval n as a measure of the ratio between the dynamic friction between the casing tube 31 and the substrate 1 and the static friction of the substrate 1, a multiplication factor AP; n for a measurement interval n as measure for the ratio between the virtual cone resistance qc; p; for; n and the net pressing force Pnet; n, a surface A as a measure for the surface of the projection of the pole foot 32 on a horizontal surface in square meters, a circumference 0 as measure for the outer circumference of the casing tube 31 in meters, a length of Lintervai as a measure for the length of one measurement interval n in meters, for example a Lintervai of 0.1 meter.

Some of the aforementioned parameters are shown in Figure 5, where P 1 = the gross pressure force P gross; n, P 2 = the net pressure force P net; n, P 3 = the cumulative dynamic friction force P dynwriving; 1—> n-l ·

The effective vertical soil stress δ'ν; η and the effective cohesion c'n are predetermined by means of a probe or bore with laboratory tests, as part of a soil survey to be carried out on the construction site as part of the design of foundations according to the applicable building regulations. The factors Fdyn; n and AP; n are values that can be determined empirically in advance on the basis of a sounding, other soil investigation or from known data from a series of occurring soil types.

The method for determining the bearing capacity of the soil displacing screw drill pile 6 comprises the following steps; - measuring the minimum net pressure force Pnet, by means of the first sensor 41 during the fitting of the drill 3 at equal measuring intervals, which is necessary to effect a vertical displacement of the pole foot 32 of the screw drill 3 in the substrate 1, and / or measuring the minimum gross pressing force P gross by means of the second sensor 42 during the fitting of the drill 3 with the same measuring intervals, which is necessary to effect a vertical displacement of the screw drill 3 in the substrate 1, and calculating the net pressure force Pnet, -n from the gross pressure force P gross with:

wherein the Pnet after the first measuring interval is equal to P gross because there is then still no significant dynamic friction Pdyn friction in the first interval, the Pdyn friction being derived at later measurement intervals from the determined virtual cone resistance qC; p; for according to the method steps as described below, calculating the virtual cone resistance qC; p; for based on the Pnetto just measured or determined and the empirically determined multiplication factor AP; n with the algorithm

calculating, on the basis of the virtual cone resistance qc; p; n, obtained from this first measuring interval, the bearing capacity of the soil displacing screw bored pile 6 and / or from the derived geotechnical parameters with the method as described in the following for the second sensor 42,

The load-bearing capacity of the displacing screw-pile 6 is calculated for each interval on the basis of the cone resistance qc; p; for and the parameters obtained from the above algorithms. Depending on the applicable building codes, algorithms are applied to the obtained parameters for the entire piered pile length. From this, and from data obtained from a soil survey under the pile base that was carried out beforehand for the design, a value follows that determines the bearing capacity of the soil displacing screw drill pile 6 at a specific depth of the pile base 32.

When the minimum gross pressing force measured by means of the second sensor 42 during the fitting of the screw drill 3 is used, the following steps are performed: deriving the effective internal friction angle cp'p; For; n from the virtual cone resistance qc; p ; before, calculating tangent cpp; na; n using the tangent of the effective internal friction angle cp'p; na; n and the empirical relationship Rtg (q> '); n, calculating Kh; na; n with using the tangent of cp'p; na; n and the empirical relationship RK; n between the tangent of φ'ρ; ΐΒ; η and Kh; na; n calculating the cumulative dynamic frictional force Pdynwrijvcum; i -> ni op basis of the predetermined effective vertical ground tension δν; η, and the empirically determined factor Fdyn; n with the algorithm

repeating the previous method steps for each subsequent measuring interval, the cumulative dynamic frictional force Pdynwrivingcum; ii> ni increasing as the screw drill 3 moves further vertically downwards into the substrate 1, the virtual cone resistance Pc; p; for for each of the measurement intervals can be determined.

The load-bearing capacity of the soil-displacing screw-drill pile 6 is calculated for each interval on the basis of the cone resistance qc; p; for and the parameters obtained from the above algorithms. Depending on the applicable building codes, algorithms are applied to the obtained parameters for the entire piered pile length. From this, and from data obtained from a soil survey under the pile base that was carried out beforehand for the design, a value follows that determines the bearing capacity of the soil displacing screw drill pile 6 at a specific depth of the pile base 32.

The sounding device is not shown in any of the figures, because its functionality is only used virtually. In other words: the sounding device is simulated. With a probing device, a probing rod with the cone on its underside can be fitted in the substrate 1. The shaft above the cone and the cone of such a probing device are then provided with various sensors, for measuring one or more properties of the substrate 1.

Determining the bearing capacity of the soil displacing screw drill pile 6 can be carried out simultaneously with the insertion of a screw drill 3, wherein the positioning assembly 2 is provided with a measuring device 4 therefor.

The above description is included to illustrate the operation of preferred embodiments of the invention, and not to limit the scope of the invention. Starting from the above explanation, many variations will be evident to those skilled in the art that fall within the spirit and scope of the present invention.

Claims (10)

What is claimed is: 1. A method for placing a ground-penetrating screw drill pile in a subsurface by means of a screw drill and a placement assembly, wherein the screw drill is provided with a steel casing pipe which is coupled at the bottom to a pole foot, the placement assembly being provided with a frame, of a broker placed on the frame, along which a drive motor with a coupling placed on its underside and rotated by the drive motor can move up and down to which the casing of the screw drill is coupled, the method comprising the following steps includes; transferring the rotary movement of the coupling to the screw drill, wherein the coupling exerts a pressing force on the screw drill, rotating the screw drill in the ground, the screw drill displacing a soil volume in the ground of at least 70% of the volume that the screw drill occupies in the ground, the installation of concrete in the space occupied by the screw drill in the subsurface, the retraction of the screw drill, and the hardening of the concrete to a ground displacing screw drill pile, the method further taking the step comprises of receiving or diverting the net pressing force exerted by the pole foot on the substrate during the rotation of the screw drill into the ground, the bearing force of the soil displacing screw drill pole being derived on the basis of the net pressing force. 2. Method as claimed in claim 1, wherein the positioning assembly is further provided with a measuring device for determining the bearing capacity, wherein determining the bearing force of the soil displacing screw drill pile is carried out with the aid of the measuring device, wherein the measuring device comprises sensors and an information processing unit, wherein the step of determining the bearing power of the soil displacing screw drill pile with the aid of the measuring device comprises the following steps; determining measured values with the sensors; supplying the measured values of the sensors to the information processing unit; performing algorithms on the measured values for calculating the bearing capacity of the soil displacing screw drill pile. 3. Method as claimed in claim 2, wherein during the rotating of the screw drill in the ground over the insertion path for several measuring intervals the steps of determining measured values with the sensors are carried out; supplying the measured values of the sensors to the information processing unit; performing algorithms on the measured values for calculating the bearing capacity of the soil displacing screw drill pile. 4. Method as claimed in claim 2 or 3, wherein the screw drill is provided at the location of the pole foot with a first sensor for taking up a net pressure force exerted on the ground by the pole foot, wherein one of the measured values is the net pressure force of the base is on the surface. The method of claim 4, wherein the first sensor is included between the casing tube and the pole foot. A method according to claim 4 or 5, wherein a software program can be loaded into the information processing unit which, when executed, simulates a cone resistor, the executed algorithms comprising at least one of the following group of algorithms; calculating a cone resistance qc; p; for; n as a measure of the pressure that a cone of a probing device would have exerted if it had been provided at the location of the screw drill in the still untouched surface prior to the application of the screw drill, by dividing the net pressing force Pnet; n by an area A as a measure for the area under the pole foot, and by multiplying the result thereof by a multiplication factor AP, n as a measure for the ratio between the cone resistance qc; p; for; n and the net pressing force Pnet; n divided by the area A. A method according to any one of claims 2-6, wherein the placement assembly is provided with a second sensor for receiving a gross pressure force exerted by the coupling on the casing tube, one of the measured values being the gross pressure force of the placement assembly on the screw drill. A method according to claim 7, wherein a software program can be loaded into the information processing unit which, when executed, simulates a cone resistor, the executed algorithms comprising at least one of the following group of algorithms; calculating a net pressure force Pnet as a measure of the force that the pole foot exerts on the substrate by reducing the gross pressure force P gross, -n on the screw drill with a cumulative dynamic friction force Pdyn friction, as a measure for the cumulatively built-up frictional force between the casing of the threaded drill and the substrate, calculating the cumulative dynamic frictional force Pdynwrijvcum; i -> ni, where n is the measurement interval in which is measured, an effective vertical ground tension δ'ν; η, per passed measurement interval a coefficient of the horizontal ground pressure Kh; na; n and a tangent of the angle of effective internal friction (p'na; n multiplying each other by adding the effective cohesion c'n to the result thereof or instead of take this multiplication and sum the wall adhesion fadh; n and by multiplying the result thereof by a circumference 0 as a measure of the circumference of the pipe sleeve e n with a length of Lintervai as a measure of the always equal measuring interval, and by multiplying the result thereof by a factor Fdyn, -n as a measure of the ratio between the dynamic friction between the casing pipe and the substrate and the static friction of the substrate and summing the calculated dynamic friction of the individual intervals passed by the threaded drill, calculating a cone resistance qc; p; for; n as a measure of the pressure that a cone of a probing device would have exerted if it had been applied on site of the threaded drill in the still untouched surface prior to the application of the threaded drill, by dividing the net pressing force Pnet; n by an area A as a measure for the area below the pole foot, and by multiplying the result thereof by a multiplication factor A p, n as a measure of the ratio between the cone resistance qc; p; for; n θη the net pressing force Pnet; n divided by the area A. 9. Placement assembly which is clearly intended and suitable for use in the method according to claims 1-8, which placement assembly comprises a measuring device, wherein the measuring device comprises sensors and an information processing unit, wherein the sensors are connected to the information processing unit for supplying measured values, wherein a software program is loaded into the information processing unit which, when executed, simulates a cone resistance, from which the bearing capacity of a soil displacing screw drill pile can be determined. Measuring device which is clearly intended and suitable for use in the method according to claims 1-8, wherein the measuring device comprises sensors and an information processing unit, wherein the sensors are connected to the information processing unit for supplying measured values thereto, the information processing unit loads a software program which, when executed, simulates a cone resistance, from which the bearing capacity of a soil displacing screw drill pile can be determined.