EP2868806B1 - Method for determining a soil parameter, and soil compaction test device - Google Patents

Description

The invention relates to a method for determining a characterizing a soil size according to the preamble of claim 1, for example, for assessing a done by a compression element compaction of the soil, as well as a soil compaction or Verdichtungsprüfgerät according to the preamble of the independent claim.

A method of this kind is out US 2007/0131453 A1 known.

DE 103 55 172 A1 describes a soil compaction device in the form of a mounted compressor, which can be coupled to an arm of an excavator. The attached compactor comprises a compacting element in the form of a compactor plate, which is pressed by the excavator on a surface location of a soil to be compacted. The compressor plate is coupled to a vibration generator, by means of the compressor plate is vibrated. As a result, a space region which lies below the surface location on which the compactor plate rests is compressed.

DE 10 2011 078 919 A1 describes a compaction tester with which the compaction of a soil area on its surface and also in depth can be determined. For this purpose, this device has on the one hand a probing rod ("Rammsonde") and on the other hand via a pressure plate. With this device, a so-called indirect soil testing method is performed, with which the settlement or a deformation modulus of the soil are determined. By means of the Rammsonde a penetration resistance of the soil is also determined.

Based on this, it is an object of the present invention to provide a method, in its application, a statement about a bottom characterizing size, for example, achieved by means of a cultivation compressor degree of compaction at a certain depth in the ground below a compression element of the add-on compactor after the end of made compaction can be made.

This object is achieved by a method having the features of claim 1, and by a soil compaction or Verdichtungsprüfgerät with the features of the independent claim. Advantageous developments of the invention are specified in subclaims. For the invention important features can also be found in the following description and in the drawing.

With the method according to the invention, it is possible, without the intervention of an expert and without the need for a special Bodenprüfgeräts a statement on a characterizing the soil size, such as the degree of compaction of the soil in the space below a surface point at which a compression element has attacked, hold true. This allows even when using, for example, mounted compressors, which in contrast to compactors always compact only at a discrete point, a quasi-complete quality assurance. However, the method is also conceivable when using a stationary driven roller, the use of a tester, etc. Overall, it allows the inventive method to create low cost, little time and possibly even fully automatic documentation on the compacted floor areas. The same applies to the soil compaction or compaction tester according to the invention.

Basis of the invention are various findings. Thus, for example, it has been recognized that a single parameter acquired or determined in many cases does not help to accurately determine the sought-after and soil-characterizing quantity. It is the combination of the values of different parameters that makes it possible to obtain a sufficiently unambiguous and to this extent sufficiently typifying statement concerning the sought-after and to be determined variable, which is characteristic of the examined soil. The value pairs, triples, quadruples, etc., which connect the values of different parameters (the term "value" is not necessarily to be understood in the sense of a scalar, but may also be, for example, a soil type or soil property, etc.) stored together with the respective value of the sought-after and to be determined size in a database that was previously created for example in field or laboratory experiments, but can also be expanded and completed in situ by manual input by an operator.

It is also conceivable that the database is present at a remotely located, for example centrally located, computer and is interrogated by a plurality of users, for example via radio, and fed with new parameter combinations determined in situ and with the associated quantities, which always results in a more accurate and larger and a plurality of users available database is generated.

More generally, in the method according to the invention, it is possible for the signal coupled into the ground or applied to the ground to comprise at least one of the following group: a mechanical, acoustic or electromagnetic oscillation, the response being an oscillation having an amplitude or an amplitude and amplitude / or a frequency spectrum; a load, the answer being a settlement. All listed signals are easy to generate and lead to easily detectable answers.

Further, the detected or determined soil property may include at least one of the following group: color; Water content; electrical ground conductivity; Shear strength; Odor; Grain size; Elasticity; compressibility; acoustic impedance; electrical impedance; Natural radiation; Radiation absorption. All mentioned soil properties can either automatically with corresponding sensors and / or manually detected or determined by a user.

The size to be determined and characterizing the soil may be at least one of the following group: degree of compaction; Load capacity; Soil; Water content. With regard to the size of the "soil type", it should be noted that, at least for the time being, their knowledge is in many cases a prerequisite for determining the other sizes mentioned.

As already mentioned above, the database used in step c) may have been created in field trials or at least optimized. For this purpose, it can be adapted or expanded by a manual input during the execution of the method, in particular by manually entering a recognized soil type (eg. Clay, sand gravel, gravel, split) and associated Paramater. Thus, the experience of the users in the creation of the database is taken into account and created over time an ever more powerful database.

An essential aspect of the present invention relates to the determination of the "best" match in step c). This may be defined, for example, by a probability that the created parameter combination is the stored parameter combination is greater than or equal to a limit value, or, more concretely, defined by a relative deviation of each parameter being less than or equal to a limit. This is easy to program and thus to automate and allows a later plausibility and thus quality control. It is also possible that in the Determining the best match the individual parameters are weighted, resulting in an individual case to an even more reliable process result.

It is also proposed that if the probability that the created parameter combination is a stored parameter combination is less than or equal to a limit value, an error message is generated. As a result, the user is warned of an uncertain result, so that he can take further measures to determine the desired size.

In a specific application, the spatial three-dimensional distribution of a relative stress below the surface point at which the compression element attaches depends, above all, on the type and geometry of the compression element used, and to some extent also on the vibration frequency of the compression element. In this case, the relative stress is understood to be the local stress at a location in the spatial area below the surface location relative to the maximum stress directly below the compression element, specifically at the end of compression, ie if further compression is no longer possible. Or, in other words: immediately below the compaction element, the relative stress at the end of compression, ie when further compaction is no longer possible, is 100% (unity, for example, [%]). However, if one removes from this surface location in the depth direction and / or lateral direction, the relative tension decreases.

For example, by a corresponding preliminary experiment, three-dimensional space shells can be determined on which the relative tension is only 90%, 80%, 70% etc. These space shells can be represented, for example, in the form of table values, polynomials, or a family of two-dimensional polynomials. Also possible is the representation, for example in the form of the values at points of a uniform grid structure in the spatial area. In the simplest case, the distribution or the course is simply indicated along a vertical line centrally below the surface location. One obtains for each compaction process one-dimensional depth values to which respective degrees of compaction are assigned. In this way, a data set or a formula is obtained for each type of compression element, which indicates the spatial distribution of the relative stress for the respective compression element, and possibly also for a specific compressor frequency.

The said distribution of the relative tension is, of course, only valid for that state in which a further operation of the compression element does not further or at least not significantly further compact the ground below the ground location. It therefore only applies to a so-called "end of compression". This can be determined, for example, by evaluating a change over time of the oscillation spectrum, in particular of a distortion factor, of the compression element during operation. If the change in harmonic distortion per unit time falls below a certain limit, then the compression end is assumed at which the relative stress at the surface location immediately below the compacting element is 100%.

Another basis of the present invention is the knowledge of the during compaction of the Compression element applied to the surface location ballast, so the force with which the compression element presses on the surface surface (unit, for example, [N]). In the case of a mounted compactor, for example, this consists of a static load and a dynamic load. The static load is the load or force with which, for example, an excavator to which the attachment compactor is attached pushes it onto the surface location. But the static load can also simply be a weight force.
The dynamic load is that additional force component that is applied to the surface location due to the vibration generated, for example, by an imbalance generator from the compacting element. It can be obtained, for example, by a vibration sensor and multiple integration of the signal obtained therefrom.

According to the invention, an absolute voltage (unit, for example, [N / m ² ]) is obtained from the relative stress, the load and the effective area of the compacting element. In the simplest case, this is the relative voltage multiplied by the determined load and divided by the effective area of the compression element. In this way, one obtains a three-dimensional spatial distribution of the absolute stress in the soil for the compaction element in a spatial region below the surface location. The absolute voltage can be calculated, for example, in the form of evenly distributed points in the spatial area below and laterally of the surface location, depending on the form in which the data of the relative voltage is present. For example, one obtains a three-dimensional grid at whose grid points the respective absolute voltage is known. But also possible is the determination the absolute stress as a three-dimensional polynomial or as a family of two-dimensional polynomials, etc ..

Another important element of the present invention is the recognition that a degree of compaction (unit dimensionless or, for example, [%]) at a certain point in the soil is dependent on the absolute stress generated there and on the type of compacted soil. For example, the degree of compaction at the same absolute tension in a shear-resistant / non-cohesive soil is different than in a low-shear and usually cohesive soil. In particular, in cohesive soils, the respective degrees of compaction are also dependent on the water content. For example, in a preliminary experiment, a database is created for the method according to the invention in which the relationship between absolute stress and degree of compaction is stored for typical soils (for example gravel, loam, dry soil, moist soil, etc.).

To carry out the method, therefore, the type of soil below the surface location at which the compaction element attaches, determined as a characterizing the soil with the above-mentioned inventive method and then depending on the determined, or determined type of soil from the previously calculated Absolute voltage determines the degree of compaction. Depending on the type of data in which the relative voltage is present, one obtains, for example, at discrete grid points, along two-dimensional curves, on a three-dimensional space shell or simply along a contour line, a value for the degree of compaction present there.

It is particularly advantageous if a desired minimum degree of compaction is predetermined and then that spatial, ie three-dimensional area below the surface location at which the compaction element has been applied is determined, up to which the predetermined minimum compaction degree is present starting from the compaction element. This gives information about the position or spatial three-dimensional extent of that region in which the predetermined degree of compaction is ensured.

The determined data can preferably be stored together with a geographical position in a database. The geographical position may be, for example, a reference position of the compression element, or the like, and this may be determined using a satellite positioning system.

The soil compaction system according to the invention is designed to carry out the method described above. For this purpose, the soil compaction system has suitable detection means, for example in the form of sensors, as well as storage, processing facilities, power supplies, input devices for manual input of data, display devices for the display of acquired data, etc., at a suitable location.

It will be appreciated that the individual processing devices provided for carrying out the above-mentioned method in the soil compacting system may be formed as software modules on a computer system, such as a notebook or a tablet PC. It goes without saying Further, for example, only the detection means may be arranged at the compression element, whereas the memory, processing means, input means, or the like can be arranged outside of the compression element, for example in the cab of an excavator.

The transmission of the variables detected by the detection devices, or of the signals corresponding to them, can be wired or wireless to the processing devices, memories, etc. A corresponding add-on compactor may have its own power supply, which supplies the detection devices with electricity, and which is supplied for example directly or indirectly from the eccentric drive, or it is a power supply of that device possible, to which the add-on compactor is mounted, for example, an excavator.

To automate the above-mentioned method, the soil compaction system according to the invention advantageously has a detection device which detects at least one parameter characterizing a type of soil at the surface location. These parameters include, for example, a water content, a color, a frequency spectrum, a reaction force, a Einsinkweg, a time course of a settlement, a signal delay, etc. It is also conceivable that a database is present in the geographic points for certain species of the soil or at least certain parameters belonging to a type of soil are stored. If, for example, the position of the compaction element is known with the aid of a location system, the corresponding parameters can be retrieved from said database.

In the simplest case, the type of floor can be manually entered by a user by means of an input device.

• Figur 1 eine schematische Darstellung eines Bodenverdichtungssystems mit einem Anbauverdichter mit einem Verdichtungselement;
• Figur 2 eine schematische Darstellung der Grundprinzipien eines Verfahrens zum Ermitteln einer einen Boden unter dem Verdichtungselement von Figur 1 charakterisierenden Größe;
• Figur 3 einen schematischen Schnitt durch den Boden an einer Oberflächenstelle, an der das Verdichtungselement von Figur 1 angreift;
• Figur 4 ein Blockschaltbild des Bodenverdichtungssystems von Figur 1; und
• Figur 5 ein Flussdiagram eines Verfahrens zum Betreiben des Bodenverdichtungssystems von Figur 1 zum Ermitteln eines Verdichtungsgrads.

Likewise, it is possible for the soil compaction system according to the invention to comprise a reservoir in which, for at least two different types of compaction elements, in each case data which characterize a distribution of the relative stress in the soil in a spatial area underneath the compaction element are stored, and a detection device is included, which detects the type of compaction element used, and / or an input device with which the type of compaction element used can be entered manually. In this way, the inventive method can be applied to the construction site with very different compression elements with a very good statement.
Hereinafter, an exemplary embodiment of the invention will be explained with reference to the drawings. In the drawing show:

• FIG. 1 a schematic representation of a soil compaction system with a cultivation compressor with a compression element;
• FIG. 2 a schematic representation of the basic principles of a method for determining a a bottom under the compression element of FIG. 1 characterizing size;
• FIG. 3 a schematic section through the bottom at a surface location at which the compression element of FIG. 1 attacks;
• FIG. 4 a block diagram of the soil compaction system of FIG. 1 ; and
• FIG. 5 a flow diagram of a method for operating the soil compaction system of FIG. 1 for determining a degree of compaction.

A soil compaction system contributes in FIG. 1 overall, the reference numeral 10. It includes a cultivation compressor 16 which is mounted on an arm 14 of an excavator 12. The cultivation compressor 16 comprises a compression element in the form of a compressor plate 18, which in the in FIG. 1 shown operating situation at an in FIG. 1 narrow dashed line surface point 20 of a bottom 22 is attached.

On the add-on compactor 16, a total of four detection devices in the form of sensors 24, 26, 28 and 30 are present. The sensor 24 detects vibrations of the compressor plate 18, the sensor 26 a force (static load), with the compactor plate 18 is pressed by the excavator 12 on the surface surface 20, the sensor 28 one or more parameters, the bottom property of the bottom 22 at the Surface character 20 and sensor 30 characterize the type of compactor plate 18 used on crop compactor 16. Typical soil characteristics that can be detected by sensor 28 depending on the type of sensor used are color, water content, electrical conductivity, shear strength, odor (or chemical) Composition of a local outgassing), grain size, elasticity, compressibility, acoustic impedance, electrical impedance, intrinsic radiation, and / or radiation absorption.

Furthermore, a satellite-based position determination system 32, in this case by way of example a GPS system, which displays the current position of the compressor plate 18 of the add-on compactor 16, is also present on the attachment compactor 16. The signals from the sensors 24 to 30 and the GPS 32 are transmitted wirelessly to a computer system 34 of the soil compaction system 10, which is arranged in the excavator 12. The computer system 34 may be a PC, a notebook, a tablet PC, or the like.

The computer system 34 has a data memory (not shown) and a processor (not shown). The memory stores a computer program which is executed by the processor. As a result, various memory and processing devices are realized on a software basis, as will be explained below. The computer system 34 also has a display (not shown), for example in the form of a screen, and an input device (not shown), for example in the form of a keyboard, a voice input, or the like.

• Mittels der Verdichterplatte 18 wird ein Signal in Form von mechanischen Schwingungen 36 in den Boden 22 eingekoppelt. Alternativ oder zusätzlich könnten durch entsprechende Einrichtungen auch Signale in Form von akustischen oder elektromagnetischen Schwingung und/oder einer Last auf den Boden aufgebracht oder in den Boden eingekoppelt werden.

Based on the presentation of FIG. 2 Now, the basic principle of a method is explained, with which a bottom 22 under the compactor plate 18 characterizing size G is determined:

• By means of the compactor plate 18, a signal in the form of mechanical vibrations 36 is coupled into the ground 22. Alternatively or additionally, it would also be possible to apply signals in the form of acoustic or electromagnetic oscillation and / or a load to the ground by means of corresponding devices or to couple them into the ground.

With the sensor 24, a first parameter P1 in the form of a response 38 is recorded on the oscillations 36 injected into the ground with an amplitude or an amplitude and / or a frequency spectrum. If the applied signal were a load, the corresponding answer would be a settling. As already mentioned above, the sensor 28 detects a second parameter P2 in the form of a soil property. 40, a combination P1 | P2 is created in the manner of a value pair from the two determined parameters P1 and P2. It is understood that in order to determine the two parameters P1 and P2 by no means necessarily two sensors 24 and 28 are required. It is also possible, for example, that only one sensor is used and the first parameter is the measured variable itself, whereas the second parameter is a time profile of the measured variable.

The created parameter combination P1 | P2 is fed to a comparator 42. This compares the created parameter combination P1 | P2 with a multiplicity of parameter combinations [P1 | P2] _a , [P1 | P2] _b , [P1 | P2] _c ,... Stored in a database 44, wherein each of the stored parameter combinations has a parameter combination Ground (22) characterizing size [G] a, [G] _b , [G] _c , ... assigned and stored with the corresponding parameter combination. The database 44 used was previously created in field trials.
The comparator 42 determines that of the stored parameter combinations [P1 | P2] _i that best matches the parameter combination P1 | P2 created. The best match is defined by the fact that a probability that the created parameter combination P1 | P2 is the stored parameter combination [P1 | P2] _i is greater than or equal to how a limit is. In the present case, this is assumed when a relative deviation of each of the parameters P1 and P2 from the corresponding parameter P1 and P2 of the stored combination [P1 | P2] _{i is} less than or equal to a limit value. In order to improve the accuracy, it is possible that in determining the best match, the parameters P1 and P2 are weighted. If the probability that the created parameter combination P1 | P2 is a stored parameter combination [P1 | P2] _i is less than or equal to a limit value, an error message is generated.

In FIG. 46, the quantity [G] _{i associated with} the determined best matching stored parameter combination [P1 | P2] _i is set as the ground-determining quantity G to be determined. The size G may be a degree of compaction, a bearing capacity, a soil type, or a water content. In the present case, it is assumed by way of example that the size G is the type of soil. With the method just described, the type of soil 22 (ie, for example, loam, sand, gravel, gravel or split, in each case moist or dry) is determined below the compactor plate 18.

The database 44 used above can be adapted or extended by manual input during the execution of the method, in particular by manual entry of a recognized soil type (eg clay, sand gravel, gravel, split) and an associated parameter combination P1 | P2.

In FIG. 3 are the compressor plate 18 and the surface area 20 as well as lying below the surface area 20 space portion 48 of the bottom 22nd shown enlarged. An arrow 50 is intended to characterize the force with which the compactor plate 18 presses on the surface surface 20. This force is composed of the static load determined by the sensor 26 and a force component caused by vibrations of the compressor plate 18, which are generated by a vibration generator, not shown. By the force 50 of the bottom 22 is compressed in the space area 48.

In this case, it is assumed that a further compression of the spatial area 48 is no longer possible if a time change of a harmonic distortion, which is determined by means of the signal of the sensor 24, falls below a limit value. If this is determined, it can be assumed that a relative stress at the surface location 20 immediately below the compressor plate 18 is at a maximum, ie at 100%. This three-dimensional space shell or "relative isobaric shell" is in the two-dimensional representation of FIG. 3 indicated by a dashed line 52a.

Depending on the type of the compressor plate 18, the relative stress develops differently as the distance from the compressor plate 18 increases. For the compressor plate 18 used here are in the two-dimensional representation of FIG. 3 By way of example, lines of equal relative stress (ie "relative isobars") are shown in dashed lines. A line 52b stands for a relative tension of 92%, a line 52c for a relative tension of 62%, and a line 52d for a relative tension of 10%. It can be seen from the present two-dimensional representation of FIG. 3 in that the lines of equal relative stress are similar to the shells of a Spread the onion starting from the surface location 20 spatially three-dimensionally into the ground 22.

Knowing the force 50 and the effective area of the compactor plate 18, an absolute voltage (eg with the dimension N / m ² ) can be determined from the known dimensionless relative stress 52. Knowing the determined type of soil 22 - as described above with reference to FIG. 2 has been explained - can be determined from this again a spatial three-dimensional distribution of a degree of compaction. A degree of compaction of 0.7 is exemplary in the two-dimensional FIG. 3 indicated by a dashed line by the reference numeral 54. For a space area 55 which lies between the compressor plate 18 and the line 54, and the in FIG. 3 is shown dotted, thus a degree of compaction of at least 0.7 can be guaranteed.

For determining the space area 55, the soil compaction system 10 has, as shown FIG. 4 It can be seen, through various illustrated by functional blocks devices that are implemented by software programs of the computer system 34. Thus, the soil compaction system 10 has a processing device 56, which determines based on the signals of the sensor 24 a Verdichtungs progress per time of the bottom 22 at the surface location 20 and then, if this compression progress per time falls below a threshold, by means of a device 58 outputs a signal , which signals a compression end. If such a compression end has been detected, function blocks are started, which in the block diagram of FIG. 4 are delimited by a dot-dashed block 60.

In a memory 62, the respective distributions of the relative voltage are stored for different types of compressor plates 18. On the basis of the signal of the sensor 30, a distribution of the relative voltage corresponding to the specific compressor plate 30 is supplied to a processing device 64. This also receives the signals from the sensors 24 and 26, from which the processing device 64 calculates the above-mentioned force 50.

From the force 50 and from the relative voltage retrieved from the memory 62, a distribution of an absolute voltage in the space region 48 below the compactor plate 18 is determined in the processing device 64. This is fed to a processing device 66, which receives from a memory 68 in which is stored for different types of soil in each case a relationship between the absolute voltage and a degree of compaction corresponding to the specific soil type here connection. This is determined by a selection device 70 on the basis of the determined soil type (see above explanations in connection with FIG. 2 ).

By means of an input device 72 (for example a keyboard of the computer system 34) a minimum desired degree of compaction, in the above example a degree of compaction of 0.7, can be entered. The desired degree of compaction is supplied to a processing device 74, which also receives the distribution of the actual degree of compaction from the processing device 66. This processing device 74 determines that area (reference numeral 55 in FIG FIG. 3 ), up to that starting from the Compressor plate 18 of the entered minimum compression ratio of 0.7 is present. The data characterizing this area are stored in a memory 76 together with the corresponding geographical position determined by the GPS 32.

A method of operating the soil compacting system 10 is as follows ( FIG. 5 After a start in 78, the type of soil 22 at surface location 20 is determined at 80 (as discussed above in connection with FIG FIG. 2 explained), wherein this method step can also be performed later. In FIG. 82, the compactor plate 18 of the attached compactor 16 is set at the surface location 20, and in FIG. 84, the attached compactor 16 is operated. In 86, the load 50 is determined and at 88 the end of compression. In 90, the operation of the attached compactor 16 is ended. In FIG. 92, the absolute stress in the bottom 22 for the particular compactor plate 18 in the space area 48 below the surface location 20 is determined, depending on the relative stress in the bottom 22 in the space area 48 below that determined for the specific compactor plate 18 at the end of compression Compressor plate 18 and depending on the determined ballast 18. In 94, a "space shell" is determined, which limits the range to which, starting from the compactor plate 18, the minimum degree of compaction predetermined in 72 is present. In 96, the data characterizing the area determined in 94 is stored together with the geographical position. The procedure ends in 98.

Thus, the invention relates to a method for assessing a compaction of a floor 22 with a stationary compacting element 18, which method following steps include: a. Determining a type of bottom 22 at a surface location 20 of the floor 22; b. Operating the compaction element at the surface location 18; c. Determining a load 50, with which the compression element 18 presses on the surface location 20 during operation, characterizing size; d. Terminating the operation of the compacting element 18 when it is detected that a compaction progress per time of the bottom 22 at the surface location 20 is below a threshold compression end; e. Determining an absolute stress in the bottom 22 for the compression element 18 in a space region 48 below the surface location 20, i depending on a relative to the compression element 18 previously determined at compression end relative stress in the bottom 22 in the space portion 48 below the compression element 18 and ii depending on the determined ballast 50; f. Determining a degree of compaction i as a function of the determined distribution of the absolute voltage and ii depending on the type of soil 22.

As well as such a method further comprising: h. Specifying a minimum degree of compaction; i. In step g: determining a region 55 below the surface surface 20, to which, starting from the compression element 18, the predetermined minimum degree of compaction is present.

As well as such a method in which the data obtained in steps g or i are stored together with a geographical position in a memory 76.

As well as a soil compaction or compaction tester 10 comprising a compaction element 18 for compaction of a soil 22 in a space area 48 below one Surface location 20, further comprising: a first magnitude detection means 24 which characterizes a compaction progress per time of the bottom 22 at the surface location 20; b. a second size detection means 26 which characterizes an over-load 50 which presses the compression member 18 onto the surface location 20 during operation; c. a memory 62 in which data indicative of a distribution of the relative stress in the bottom 22 in a space area 48 below the compression element 18 for the compression element 18 is stored; d. a memory 68 in which a relationship between an absolute voltage and a degree of compaction is respectively stored for at least two types of bottom 22; e. a selector 70 with which one type of floor 22 can be selected; f. a processing device 56 which outputs a signal when a compaction progress determined by the first size per time of the bottom 22 at the surface location 20 falls below a threshold value; G. a processing device 64 which determines data characterizing a distribution of an absolute voltage in the ground 22 in the space area 48 below the compacting element 18, i depending on the data stored in the memory 62 according to c and ii depending on the detected load 50; and h. a processing device 66, which determines i depending on the data determined in step g and ii depending on the selected type of soil 22 data that characterize a distribution of a degree of compaction.

As well as such a soil compaction or compaction tester 10, which further comprises: i. an input device 72, with which a desired minimum Degree of compaction can be entered; and J. a processing device 74, which determines data that characterize a region 55, to which, starting from the compression element 18, the entered minimum degree of compaction is present.

As well as such a soil compaction or compaction tester 10, which further comprises: k. a positioning system 32, preferably a satellite-based positioning system; and l. a memory 76 in which the data obtained in steps h or j can be stored together with the geographical position determined by the position determining system 32.

As well as such a soil compaction or compaction tester 10, which further comprises: m. a device 24, 28 which is designed such that it allows the determination of a size G characterizing the bottom 22 at the surface location 20, and / or an input device with which at least one size G characterizing the bottom at the surface location can be entered manually ; wherein the selector 70 according to the above feature e selects a kind of the floor 22 from the determined or inputted size, or the size itself characterizing the floor itself is the kind of the floor.

As well as such a soil compaction or compaction tester 10, which further comprises: a memory 62 in which, for one or more different types of compaction elements 18, respectively, data representing a distribution of the relative stress in the soil 22 in a space region 48 below the compaction element 18 characterize, are stored; o. a detection device 30, which detects the type of compression element 18 used, and / or an input device with which the type of compression element used can be entered manually; wherein the processing means 64 according to feature g, the data stored for the detected or input type of the compression element 18 and the distribution of the relative voltage characterizing data used.

Claims (11)

1. Method for determining a value (G) characterizing a soil (22), which method comprises the following steps:

   a) detection or determination of parameters (P1, P2) in the form of a soil property and/or in the form of a response (38) to a signal (36) coupled into or applied to the soil (22), wherein each parameter (P1, P2) in itself is not yet typical of the value (G) to be determined;

   b) production of a combination (P1|P2) of at least two of the parameters determined and/or detected;

   c) comparison of the combination (P1|P2) produced with corresponding parameter combinations ([P1|P2]_i) which are stored in a database (44) together with values ([G]_i) assigned thereto and characterizing a soil (22), thus determining the stored parameter combination ([P1|P2]_i) which best correlates with the parameter combination (P1|P2) produced;

   d) establishment of the soil characteristic value (G) to be determined as the value ([G]_i) which is assigned to the stored parameter combination ([P1|P2]_i) determined as presenting the best correlation.
2. Method according to claim 1, characterized in that the signal (36) coupled into or applied to the soil (22) comprises at least one of the following group: a mechanical, acoustic or electromagnetic vibration, wherein the response is a vibration with an amplitude or an amplitude and/or frequency spectrum; a load, wherein the response is a settlement.
3. Method according to one of claims 1 or 2, characterised in that the soil property (P2) detected or determined comprises at least one of the following group: colour; water content; electrical soil conductivity; shear strength; odour; grain size; elasticity; compressibility; acoustic impedance; electrical impedance; inherent radiation; radiation absorption.
4. Method according to any of the preceding claims, characterised in that the value (G) to be determined is at least one of the following group: degree of compaction, in particular a spatial three-dimensional distribution of the degree of compaction; load-bearing capacity; soil type; water content.
5. Method according to any of the preceding claims, characterised in that the database (44) used in step c) is produced in field tests.
6. Method according to any of the preceding claims, characterised in that the database (44) used in step c) is adapted or extended by manual input during performance of the method, in particular by manual input of a detected soil type (e.g. clay, sand-gravel, gravel, grit) and associated parameters (P1|P2).
7. Method according to any of the preceding claims, characterised in that in step c), the best correlation is defined in that the probability of the parameter combination (P1|P2) produced being the stored parameter combination ([P1|P2]i) is greater than or equal to a limit value.
8. Method according to claim 7, characterised in that in step c), the best correlation is defined in that a relative deviation of each parameter (P1, P2) is less than or equal to a limit value.
9. Method according to claim 8, characterised in that in determination of the best correlation, the parameters (P1, P2) are weighted.
10. Method according to any of claims 7 to 9, characterised in that an error message is generated if the probability of the parameter combination (P1|P2) produced being a stored parameter combination ([P1|P2]_i) is less than or equal to a limit value.
11. Soil compaction or compaction test device (10), characterised in that it comprises a control or regulator apparatus (34) which is programmed and/or configured to perform a method according to any of the preceding claims.

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