DE102020132736A1 - Method for the analysis of heterogeneous rock and / or soil samples, preferably drill cores - Google Patents

Abstract

The invention relates to a method for analyzing a heterogeneous rock and / or soil sample, preferably a drill core (100), a first and a second sensor-supported, contactless and non-destructive chemical-physical analysis being correlated with one another in relation to the measurement position by means of a control (30) , wherein the first sensor-based and non-contact and non-destructive chemical-physical analysis is carried out by means of an XRF sensor (20) and the second sensor-based and non-contact and non-destructive chemical-physical analysis is carried out by means of a RAMAN sensor (21) The method also includes a sensor-based and contactless chemical-physical analysis using a LIBS sensor (22), which is related to the measurement position with the first and / or the second, respectively sensor-based, contactless and non-destructive chemical-physical analysis using the controller (30) is brought into correlation and a first sensor-based optical analysis using an HSI sensor (23).

Description

The invention relates to a method for analyzing a heterogeneous rock and / or soil sample, preferably a drill core, wherein a first and a second sensor-supported, contactless and non-destructive chemical-physical analysis are correlated with one another by means of a control based on the measurement position.

From the US 8,538,697 B2 a method is known in which core samples are scanned by means of several methods, such as X-ray fluorescence scanning, neutron bombardment, ultrasound, spectroscopy and multispectral imaging. During a scan, the linear position and the orientation are stored in the core sample. A virtual core sample is also created and displayed on a computing device. The appearance of the actual core is simulated.

From the US 2016/0266275 A1 discloses a method for quantifying minerals in a formation sample, for example an oil field reservoir sample, in which a common inversion of DRIFTS spectra (infrared Fourier transform spectroscopy with diffuse reflectivity) and XRF data (X-ray fluorescence) is used.

From the US 8,234,912 B2 a device for the continuous measurement of a geomaterial is known. The device comprises a measuring device with a moving head which can be moved in a longitudinal direction relative to a core portion of the geomaterial. Probes can be coupled to the head to measure properties of the core section. The measurement is neither contactless nor non-destructive.

From the WO 2009/101265 A1 a method for analyzing core and / or drilling chip samples and a corresponding analysis device are known. The core is analyzed by passing it through the analysis device. From the WO 2013/180922 A1 a method for analyzing a soil sample using XRF and RAMAN spectroscopy is known. With a location module, a position of the device used for the analysis can be determined, for example by GPS, in order to be able to assign the analysis data geographically, that is to say to a measurement location. Also from the DE 11 2013 004 743 T5 a method for analyzing geological patterns by means of various methods such as XRF and RAMAN is known. In the case of the three aforementioned solutions, however, the analysis is not carried out in relation to the measurement position, so that the results of the analysis are only known for the entire sample or the entire sample.

From the WO 2017/155450 A1 discloses a system and method for measuring, collecting and processing data on physical characteristics of drill core samples. The system includes a non-contact analysis device for measuring and collecting data from the outer surface of the drill core samples and a processing unit to extract physical features as output. The data from the analysis device and the data relating to physical characteristics of the drill cores are stored in storage devices. In this process, no analyzes are correlated with one another.

From the WO 2011/146014 A1 an apparatus and a method for analyzing core and / or drill chip samples are known. The device comprises a receptacle for at least one sample and an analysis unit, which are arranged to be movable relative to one another, the receptacle being arranged to be movable in a first direction (X direction). A scanning path along the sample can be followed with the analysis unit. Determines the position of a comb path of the sample during analysis scanning. The relative position between the analysis unit and the sample is controlled as a function of the comb path, so that a correspondence between the scanning path and the comb path is continuously established and maintained during the analysis scanning process. In this process, no analyzes are correlated with one another.

From the US 6,628,322 B1 a three-axis guide unit with an attached measuring head is known. There is no reference to the analysis of rock or soil samples.

The invention is therefore based on the object of providing a method with which an improved analysis of chemical-physical characteristics of a rock and / or soil sample is made possible.

This object is achieved by a method with the features of claim 1 and an analysis system with the features of claim 18. Advantageous embodiments of the invention are specified in the dependent claims and the description below.

According to the invention, an improved method for analyzing a heterogeneous rock and / or soil sample, preferably a drill core, is created in that a first and a second sensor-based, contactless and non-destructive chemical-physical analysis are correlated with one another by means of a control based on measurement positions the first sensor-based and contactless as well non-destructive chemical-physical analysis is carried out using an XRF sensor and the second sensor-based, contactless and non-destructive chemical-physical analysis is carried out using a RAMAN sensor.

In other words, there is a chemical-physical analysis of the rock and / or soil sample by means of an XRF sensor and a further chemical-physical analysis of the rock and / or soil sample by means of a RAMAN sensor. The two analyzes are correlated with one another in relation to the measurement position by means of a control, thus automated.

In relation to the measurement position, it is understood that the results of the analysis can each be clearly assigned to a measurement position on the rock and / or soil sample. In other words, the respective, in particular lateral, measuring position on the rock and / or soil sample is known and the respective result of the analysis can thus be clearly assigned to the, in particular lateral, measuring position or vice versa. The respective result data of an analysis at a measuring position are therefore connected or linked in terms of data technology to position data of this measuring position, in particular by the control.

It is of course possible that consequently the results of the analysis can each be clearly assigned to a position at the location where the rock and / or soil sample was taken, in particular to a vertical position in a borehole. This is possible because, in addition to knowing the measurement position on the rock and / or soil sample itself, the removal position of the rock and / or soil sample is also known. In contrast to the WO 2013/180922 A1 known solution can not only connect (via GPS) determined global coordinates of a location at which the analysis is carried out with the respective rock and / or soil sample or the results of the analysis related to the entire rock and / or soil sample to be brought.

When the two analyzes or their results are correlated with one another in relation to the measurement position, the results of the first analysis assigned to a specific measurement position are correlated with the results of the second analysis assigned to the same measurement position. After completion of all analyzes and / or after completion of one analysis, the analyzes are already correlated with one another while the other analysis is being carried out. The order in which the analyzes are carried out can be freely selected.

Sensor-supported means that at least part of the analysis is carried out by means of a sensor. The analysis is therefore based at least in part on data that are determined by means of a sensor. The sensor is connected to the controller for signaling purposes. The sensor comprises an emitter and a detector, the emitter generating and transmitting a first signal and the detector receiving a second signal, the second signal being produced by the reaction of the first signal with the rock and / or soil sample.

An X-ray fluorescence analysis of the rock and / or soil sample is carried out using the XRF sensor. The XRF sensor is known per se and is available on the market, for example, from J&C Bachmann GmbH.

A RAMAN spectroscopy of the rock and / or soil sample is carried out using the RAMAN sensor. The RAMAN sensor is known per se and is available on the market, for example, from Timegate Instruments Ltd.

The rock and / or soil sample is preferably a drill core made of hard or loose rock. However, it is also conceivable that the rock and / or soil sample comprises loose material, in particular drill cuttings, so-called tailings, powder pellets or dust. A complex preparation of the rock and / or soil sample is not necessary.

The rock and / or soil sample is heterogeneous. Of course, the analysis according to the invention can also be used on homogeneous rock and / or soil samples.

The entire rock and / or soil sample, in particular its entire volume, is preferably analyzed. However, it is also conceivable that only, in particular predetermined, partial areas of the rock and / or soil sample are analyzed.

Contactless means that the analysis takes place without direct contact between the sensor used for the analysis and the rock and / or soil sample.

Non-destructive means that the rock and / or soil sample is not destroyed or damaged during the chemical-physical analysis. Destruction of the rock and / or soil sample before or after the analysis is possible, however.

The method according to the invention can take place at the location where the rock and / or soil sample was taken (“on-site”). Elaborate laboratory analyzes and the labor-intensive use of hand-held devices for the analysis of the rock and / or soil sample can, preferably completely, be dispensed with.

The method according to the invention can be used in particular in the early development phases, for example of drilling fields for the extraction of raw materials, or in drilling campaigns or in blasting or in ore processing or in ore recycling. Based on precise real-time information, a decision, especially about further drilling, can be made more quickly. Long downtimes of systems, in particular drilling machines, and unnecessary process steps, in particular unnecessary drilling, can also be avoided as far as possible. This saves time and money and reduces the environmental impact.

A combination of the chemical-physical analysis using the XRF sensor and RAMAN sensor enables, for example, the determination of the ore content in the rock and / or soil sample and the minerals in which the ore is bound. This is particularly important information for subsequent ore processing.

Particularly preferably, a third sensor-supported and contactless chemical-physical analysis is correlated with the first and / or the second, in each case, sensor-supported, contactless and non-destructive chemical-physical analysis by means of the control in relation to the measurement position. The third sensor-supported and contactless chemical-physical analysis is preferably carried out by means of a LIBS sensor.

In other words, the first analysis is correlated with the third analysis, the second analysis with the third analysis, or the first and second analysis with the third analysis in relation to the measurement position.

A so-called Laser Induced Breakdown Spectroscopy of the rock and / or soil sample is carried out using the LIBS sensor. The LIBS sensor is known per se and is available on the market, for example, from LTB Lasertechnik Berlin GmbH.

A combination of chemical-physical analysis using a LIBS sensor and chemical-physical analysis using an XRF sensor enables, for example, the analysis of chemical concentrations of elements with low and high atomic numbers.

In a particularly advantageous manner, an elementary composition and / or structure of the rock and / or soil sample or a sub-area of the rock and / or soil sample is determined qualitatively and quantitatively in the sensor-based chemical-physical analysis.

In other words, in addition to the qualitative determination of the elemental composition and / or structure, there is also a quantitative determination of the elemental composition and / or structure of the rock and / or soil sample. Due to the mutual support of the individual sensors, a precise statement on the chemical-physical composition of the rock and / or soil sample is made possible.

The combination of analyzes according to the invention thus fulfills, for example, all the requirements of a chemical, mineralogical and lithological drill core analysis. In contrast to methods known from the prior art that use individual sensors or a combination of other sensors, the method according to the invention covers a broader spectrum of measurable and relevant chemical-physical parameters for classifying the rock and / or soil sample in one operation replaces additional, direct determination procedures.

In one embodiment, it is provided that at least two of the sensor-based chemical-physical analyzes are correlated in relation to the measurement position in such a way that, for an assessment of the rock and / or soil sample, the measurement-position-related results of the sensor-based chemical-physical analysis that is most accurate for a chemical-physical characteristic are used become.

The most precise sensor-based chemical-physical analysis is that analysis which is more precise than all other sensor-based chemical-physical analyzes used for the chemical-physical characteristic in question.

The measurement position-related results are each stored in a memory unit designed and set up for this purpose.

An assignment of the most precise sensor-supported chemical-physical analysis to a chemical-physical characteristic is preferably specified. After determining a chemical-physical feature, the measurement position-related results of the correspondingly assigned chemical-physical analysis, in particular for a chemical-physical classification of the rock and / or soil sample, are used.

Alternatively, the measurement position-related results of individual chemical-physical analyzes, in particular for a classification of the Rock and / or soil sample, compared with one another and / or supplemented with one another.

In this way, for example, more precise models of deposits can be created.

In a further embodiment it is provided that at least two of the sensor-supported chemical-physical analyzes are correlated in relation to the measurement position in such a way that the rock and / or soil sample is segmented into local sections on the basis of measurement-position-related results from a previous sensor-supported chemical-physical analysis. For the respective local section, in particular by means of the controller, a lateral measurement position and / or a lateral measurement position change and / or a measurement position-related distance of the sensor used for a further sensor-based chemical-physical analysis relative to the rock and / or soil sample and / or a Measurement resolution of this sensor is determined and preferably set.

The measurement position-related results are each stored in a memory unit designed and set up for this purpose.

The lateral measurement position, the lateral measurement position change, the measurement position-related distance and the measurement resolution are adjustable parameters that can be set on the sensor itself and / or a device used to guide the sensor. The setting of the adjustable parameters takes place in each case for a local section of the rock and / or soil sample. The division of the rock and / or soil sample into local sections is carried out on the basis of measurement position-related results from a previous sensor-based chemical-physical analysis.

The lateral measurement position and / or the lateral measurement position change are determined independently of the shape of the rock and / or soil sample, in particular regardless of where the crest of the drill core is arranged.

It is conceivable that, on the basis of measurement position-related results of a second sensor-supported chemical-physical analysis, an adjustable parameter determined on the basis of measurement-position-related results of a first sensor-supported chemical-physical analysis is corrected for a third sensor-supported chemical-physical analysis.

It can also be provided that the measurement resolution is determined in relation to the position.

This results in an increased measurement accuracy compared to the prior art when carrying out the analyzes. The number of rock and / or soil samples to be examined can consequently be reduced.

The rock and / or soil sample is particularly preferably segmented into local sections by means of a first sensor-supported optical analysis. For the respective local section, in particular by means of the controller, a lateral measurement position and / or a lateral measurement position change and / or a measurement position-related distance of the sensor used for the respective sensor-based chemical-physical analysis relative to the rock and / or soil sample and / or a Measurement resolution of this sensor is determined and preferably set.

In other words, the rock and / or soil sample is divided into local sections on the basis of measurement position-related results from a first sensor-supported optical analysis. The measurement position-related results from the first sensor-supported optical analysis are each stored in a memory unit designed and set up for this purpose, preferably in the same memory unit in which the measurement position-related results from the chemical-physical analysis are also stored.

A segmentation that takes place in this way can be carried out independently or in addition to the segmentation on the basis of measurement position-related results from a preceding sensor-supported chemical-physical analysis.

It can advantageously be provided that the segmentation takes place on the basis of a geometry, color and / or surface property of the rock and / or soil sample.

In a structurally simple manner, the first sensor-supported optical analysis comprises a 3D measurement, preferably using an RGB-3D sensor, and / or hyperspectral imaging, preferably using an HSI sensor.

A combination of chemical-physical analysis, in particular using a RAMAN sensor, and hyperspectral imaging using an HSI sensor, increases the number of determinable minerals and their alterations compared to the use of individual sensors.

Advantageously, the measurement resolution and / or the lateral measurement position and / or the lateral measurement position change and / or the measurement position-related distance of the chemical for the respective or the further sensor-supported physical analysis, the sensor used depends on the fact that in the first sensor-based optical analysis or the preceding sensor-based chemical-physical analysis a homogeneous or heterogeneous local section is determined.

In other words, the sensor parameters are set as a function of the nature of the local section.

A higher measurement resolution is preferably determined for a heterogeneously designed section than for a homogeneously designed section. A slower lateral measurement position change is also preferably determined for a heterogeneously designed section than for a homogeneously designed section.

It is of course also conceivable that the same sensor setting is used for a homogeneously designed section as for a heterogeneously designed section.

In an advantageous embodiment, a position and / or orientation of the rock and / or soil sample is determined by means of a second sensor-supported optical analysis and with this a lateral measurement position and / or a lateral measurement position change of the sensor used for the respective sensor-supported chemical-physical analysis relative to the rock - and / or soil sample determined.

The second sensor-based optical analysis is preferably carried out before the sensor-based chemical-physical analyzes and / or the first sensor-based optical analysis. In particular, this results in the determination of the initial lateral measurement position and the initial lateral measurement position change of the sensor used for the respective sensor-supported chemical-physical analysis relative to the rock and / or soil sample.

The lateral measurement position and / or the lateral measurement position change are determined independently of the shape of the rock and / or soil sample, in particular regardless of where the crest of the drill core is arranged.

The results from the second optical analysis are preferably each stored in a memory unit designed and set up for this purpose, in particular in the same memory unit in which the measurement position-related results from the first sensor-supported optical and chemical-physical analysis are also stored.

Particularly preferably, a surface geometry of the rock and / or soil sample is also determined by means of the second sensor-supported optical analysis and a measurement position-related distance of the sensor used for the respective sensor-supported chemical-physical analysis relative to the rock and / or soil sample is determined.

In particular, this results in the determination of the initial measurement position-related distance of the sensor used for the respective sensor-supported chemical-physical analysis relative to the rock and / or soil sample.

Surface geometry is understood to mean the external structure of the rock and / or soil sample, in particular the drill core. This includes, for example, holes or elevations opposite an averaged outer surface and / or contour of the rock and / or soil sample.

In a structurally simple manner, the second sensor-supported optical analysis comprises a 3D measurement, preferably by means of the RGB-3D sensor.

Advantageously, the lateral measurement position along two axes of a coordinate system and the measurement position-related distance along a third axis of the coordinate system can be set independently of one another or axially superimposed, preferably by means of a three-axis guide unit.

Particularly preferably, the respective measurement resolution and / or the respective lateral measurement position and / or the respective lateral measurement position change and / or the respective measurement position-related distance of a sensor is stored so that another sensor is in each case at the same lateral measurement position and / or according to the same lateral measurement position change and / or can be arranged with the same measurement position-related distance relative to the rock and / or soil sample and / or set with the same measurement resolution.

The adjustable parameters are each stored in a memory unit designed and set up for this purpose. This storage unit is preferably the same storage unit that is also used to store the measurement position-related results from one of the chemical-physical and / or optical analyzes.

It can advantageously be provided that two sensor-based chemical-physical analyzes or one sensor-based chemical-physical and one sensor-based optical analysis, preferably by means of the HSI sensor and the XRF sensor, or two sensor-supported optical analyzes of the rock and / or soil sample can be carried out at the same time.

Such analyzes are preferably carried out at the same time which have the same or at least similar measurement speed.

This can further reduce the time required to analyze a heterogeneous rock and / or soil sample.

The rock and / or soil sample is particularly preferably stored statically during the sensor-supported chemical-physical and / or sensor-supported optical analysis.

Statically supported is understood to mean that the rock and / or soil sample is not moved during the sensor-supported chemical-physical and / or sensor-supported optical analysis.

The static storage of the rock and / or soil sample is preferably carried out by means of a measuring table or a receptacle arranged on the measuring table. However, it is also conceivable for the rock and / or soil sample to be stored in a box, preferably arranged on the measuring table.

As a result, the measurement position assigned to a measurement result can be determined more precisely than in the case of a moving rock and / or soil sample, since, for example, slipping of the rock and / or soil sample caused by the movement is avoided. In addition, due to their lower weight compared to the rock and / or soil sample, the sensors can be positioned more precisely.

The rock and / or soil sample is also preferably stored freely, in particular not clamped, that is, in particular no pressure is exerted on the rock and / or soil sample.

It is advantageously provided that the measurement position-related results from the sensor-supported chemical-physical and / or the sensor-supported optical analysis are visually displayed after they have been correlated with one another.

The display preferably includes a 3D representation of the rock and / or soil sample. The results relating to the measurement position are displayed on or next to this 3D representation of the rock and / or soil sample, preferably in each case summarized for a local section.

• • Aufnahme zur statischen Lagerung einer Gesteins- und/oder Bodenprobe
• • mindestens einen ersten und einen zweiten Sensor für eine chemisch-physikalische Analyse
• • Drei-Achsen-Führungseinheit für den ersten Sensor
• • Drei-Achsen-Führungseinheit für den zweiten Sensor
• • Steuerung, die geeignet ist, die erste und zweite jeweils sensorgestützte chemisch-physikalische Analyse messpositionsbezogen miteinander in Korrelation zu bringen
• • Speichereinheit, die geeignet ist, eine laterale Messposition und/oder eine laterale Messpositionsänderung und/oder einen messpositionsbezogenen Abstand der Sensoren relativ zur Gesteins- und/oder Bodenprobe und/oder eine Messauflösung der Sensoren zu speichern
• • Darstellungseinheit, vorzugsweise Monitor, zur visuellen Anzeige von messpositionsbezogenen Ergebnissen

The invention is also directed to a mobile analysis system with which a method for analyzing heterogeneous rock and / or soil samples can be carried out. The mobile analysis system includes:

• • Recording for static storage of a rock and / or soil sample
• • at least a first and a second sensor for a chemical-physical analysis
• • Three-axis guide unit for the first sensor
• • Three-axis guide unit for the second sensor
• • Control system that is suitable for correlating the first and second, each sensor-supported, chemical-physical analysis with one another in relation to the measurement position
• • Storage unit that is suitable for storing a lateral measurement position and / or a lateral measurement position change and / or a measurement position-related distance of the sensors relative to the rock and / or soil sample and / or a measurement resolution of the sensors
• • Display unit, preferably a monitor, for the visual display of measurement position-related results

The control is connected to each three-axis guide unit, each sensor, the storage unit and / or the display unit for signaling purposes. It is of course conceivable that the memory unit is connected directly, that is to say without the interposition of the control, to the three-axis guide unit and / or the sensors for signaling purposes.

By means of the three-axis guide unit, an exact repetition of a travel route of a sensor is ensured by the same or a different sensor. In other words, the lateral measurement position change of a first sensor can be repeated by this or a second sensor.

One of the sensors for a chemical-physical analysis is advantageously an XRF sensor or a RAMAN sensor or a LIBS sensor.

It is of course conceivable that several XRF sensors and / or RAMAN sensors and / or LIBS sensors can be used.

It can advantageously be provided that the mobile analysis system comprises an RGB-3D sensor and / or an HSI sensor.

The RGB-3D sensor and / or the HSI sensor are arranged on the three-axis guide unit for the first sensor or on the three-axis guide unit for the second sensor or on an independent three-axis guide unit.

In a structurally simple manner, all sensors, in particular for each chemical-physical analysis and / or each optical analysis, are arranged on a three-axis guide unit.

However, it is also conceivable that all sensors for each chemical-physical analysis are arranged on a three-axis guide unit and all sensors for each optical analysis are arranged on a further three-axis guide unit.

• 1 einen Schrittfolgeplan zum schematischen Ablauf einer Ausführungsform des erfindungsgemäßen Verfahrens mit XRF-Sensor, RAMAN-Sensor und RGB-3D-Sensor,
• 2 einen Schrittfolgeplan zum schematischen Ablauf einer weiteren Ausführungsform des erfindungsgemäßen Verfahrens mit XRF-Sensor, RAMAN-Sensor, LIBS-Sensor und RGB-3D-Sensor,
• 3 einen Schrittfolgeplan zum schematischen Ablauf einer weiteren Ausführungsform des erfindungsgemäßen Verfahrens mit XRF-Sensor, RAMAN-Sensor, HSI-Sensor und RGB-3D-Sensor,
• 4 einen Schrittfolgeplan zum schematischen Ablauf einer weiteren Ausführungsform des erfindungsgemäßen Verfahrens mit XRF-Sensor, RAMAN-Sensor, LIBS-Sensor, HSI-Sensor und RGB-3D-Sensor,
• 5 eine schematische Darstellung eines mobilen Analysesystems und
• 6 eine schematische Darstellung eines Bohrkerns zeigt.

Further details of the invention emerge from the following description of exemplary embodiments with reference to the drawing, in which

• 1 a step-by-step plan for the schematic sequence of an embodiment of the method according to the invention with an XRF sensor, RAMAN sensor and RGB 3D sensor,
• 2 a step-by-step plan for the schematic sequence of a further embodiment of the method according to the invention with an XRF sensor, RAMAN sensor, LIBS sensor and RGB-3D sensor,
• 3 a step-by-step plan for the schematic sequence of a further embodiment of the method according to the invention with an XRF sensor, RAMAN sensor, HSI sensor and RGB-3D sensor,
• 4th a step-by-step plan for the schematic sequence of a further embodiment of the method according to the invention with an XRF sensor, RAMAN sensor, LIBS sensor, HSI sensor and RGB-3D sensor,
• 5 a schematic representation of a mobile analysis system and
• 6th shows a schematic representation of a drill core.

The 1 shows a step-by-step plan for the schematic sequence of an embodiment of the method according to the invention with an XRF sensor 20th , RAMAN sensor 21 and RGB 3D sensor 24.

Step I: Determination of the position and orientation of the rock and / or soil sample 100 by means of the RGB-3D sensor 24 and determining a lateral measurement position LM and a lateral change in measurement position LMÄ of the XRF sensor 20th relative to the rock and / or soil sample 100 by means of the controller 30th ;

Step II: Determination of the surface geometry of the rock and / or soil sample 100 by means of the RGB-3D sensor 24 and determination of a measurement-position-related distance A. of the XRF sensor 20th relative to the rock and / or soil sample 100 by means of the controller 30th ;

Step III: Performing the first chemical-physical analysis using the XRF sensor 20th ;

Step III-A: Storage of the measurement position-related results of the first
chemical-physical analysis (XRF sensor 20th ) by means of the storage unit 60 ; Step III-B: Storage of the measurement resolution MA , the lateral measurement position LM , the
lateral change of measurement position LMÄ and the distance related to the measurement position A.
of the XRF sensor 20th during the first chemical-physical analysis by means of
the storage unit 60 ;

Step IV: segmentation of the rock and / or soil sample 100 in local
Sections 101 based on measurement position-related results from the first
chemical-physical analysis (XRF sensor 20th ) by means of the control 30th ;

Step V: Determination of a lateral measurement position LM , a lateral change in measurement position LMÄ and a measurement position-related distance A. of the RAMAN sensor 21 relative to the rock and / or soil sample 100 and one
Measurement resolution MA of the RAMAN sensor 21 for the respective local section 101 ; Step VI: Carrying out the second chemical-physical analysis using the
RAMAN sensors 21 ;

Step VI-A: Storage of the measurement position-related results of the second chemical physical analysis (RAMAN sensor 21 ) using the
Storage unit 60 ;

Step VII: correlating the measurement position-related results from the first chemical-physical analysis (XRF sensor 20th ) and the second
chemical-physical analysis (RAMAN sensor 21 ) by means of the control 30th ; Step VIII: Visual display of the measurement position-related results from the first chemical-physical analysis (XRF sensor 20th ) and the second chemical-physical analysis (RAMAN sensor 21 ) by means of the display unit 50 .

The 2 shows a step sequence plan for the schematic sequence of a further embodiment of the method according to the invention with an XRF sensor 20th , RAMAN sensor 21 , LIBS sensor 22nd and RGB 3D sensor 24.

Step I: Determination of the position and orientation of the rock and / or soil sample 100 by means of the RGB-3D sensor 24 and determining a lateral measurement position LM and a lateral change in measurement position LMÄ of the XRF sensor 20th relative to the rock and / or soil sample 100 by means of the controller 30th ;

Step II: Determination of the surface geometry of the rock and / or soil sample 100 by means of the RGB-3D sensor 24 and determination of a measurement-position-related distance A. of the XRF sensor 20th relative to the rock and / or soil sample 100 by means of the controller 30th ;

Step III: Performing the first chemical-physical analysis using the XRF sensor 20th ;

Step III- A. : Storage of the measurement position-related results of the first chemical-physical analysis (XRF sensor 20th ) by means of the storage unit 60 ; Step III-B: Storage of the measurement resolution MA , the lateral measurement position LM , the lateral change in measurement position LMÄ and the distance related to the measurement position A. of the XRF sensor 20th during the first chemical-physical analysis by means of the storage unit 60 ;

Step IV: segmentation of the rock and / or soil sample 100 in local sections 101 based on measurement position-related results from the first chemical-physical analysis (XRF sensor 20th ) by means of the control 30th ; Step V: Determination of a lateral measurement position MA , a lateral change in measurement position LMÄ and a measurement position-related distance A. each of the RAMAN sensor 21 and the LIBS sensor 22nd relative to the rock and / or soil sample 100 and a measurement resolution MA each of the RAMAN sensor 21 and the LIBS sensor 22nd for the respective local section 101 ;

Step VI: Performing the second chemical-physical analysis using the RAMAN sensor 21 ;

Step VI- A. : Storage of the measurement position-related results of the second chemical-physical analysis (RAMAN sensor 21 ) by means of the storage unit 60 ;

Step VII: Carrying out the third chemical-physical analysis using the LIBS sensor 22nd ;

Step VII- A. : Storage of the measurement position-related results of the second chemical-physical analysis (LIBS sensor 22nd ) by means of the storage unit 60 ; Step VIII: correlating the measurement position-related results from the first chemical-physical analysis (XRF sensor 20th ) and the second chemical-physical analysis (RAMAN sensor 21 ) and the third chemical-physical analysis (LIBS sensor 22nd ) by means of the control 30th ; Step IX: Visual display of the measurement position-related results from the first chemical-physical analysis (XRF sensor 20th ) and the second chemical-physical analysis (RAMAN sensor 21 ) and the third chemical-physical analysis (LIBS sensor 22nd ) by means of the display unit 50 .

The 3 shows a step sequence plan for the schematic sequence of a further embodiment of the method according to the invention with an XRF sensor 20th , RAMAN sensor 21 , HSI sensor 23 and RGB 3D sensor 24.

Step I: Determination of the position and orientation of the rock and / or soil sample 100 by means of the RGB-3D sensor 24 and determining a lateral measurement position LM and a lateral change in measurement position LMÄ of the XRF sensor 20th relative to the rock and / or soil sample 100 by means of the controller 30th ;

Step II: Determination of the surface geometry of the rock and / or soil sample 100 by means of the RGB-3D sensor 24 and determination of a measurement-position-related distance A. of the XRF sensor 20th relative to the rock and / or soil sample 100 by means of the controller 30th ;

Step III: Performing the first optical analysis using the HSI sensor 23 ; Step III- A. : Storage of the measurement position-related results of the first optical analysis (HSI sensor 23 ) by means of the storage unit 60 ;

Step III-B: Storage of the measurement resolution MA , the lateral measurement position LM , the lateral change in measurement position LMÄ and the distance related to the measurement position A. of the HSI sensor 23 during the first optical analysis by means of the storage unit 60 ;

Step IV: segmentation of the rock and / or soil sample 100 in local sections 101 based on measurement position-related results from the first optical analysis (HSI sensor 23 ) by means of the control 30th ;

Step V: Determination of a lateral measurement position LM , a lateral change in measurement position LMÄ and a measurement position-related distance A. each of the XRF sensor 20th and the RAMAN sensor 21 relative to the rock and / or soil sample 100 and a measurement resolution MA each of the XRF sensor 20th and the RAMAN sensor 21 for the respective local section 101 ;

Step VI: Performing the first chemical-physical analysis using the XRF sensor 20th ;

Step VI- A. : Storage of the measurement position-related results of the first chemical-physical analysis (XRF sensor 20th ) by means of the storage unit 60 ; Step VI-B: Storage of the measurement resolution MA , the lateral measurement position LM , the lateral change in measurement position LMÄ and the distance related to the measurement position A. of the XRF sensor 20th during the first chemical-physical analysis by means of the storage unit 60 ;

Step VII: Performing the second chemical-physical analysis using the RAMAN sensor 21 ;

Step VII- A. : Storage of the measurement position-related results of the second chemical-physical analysis (RAMAN sensor 21 ) by means of the storage unit 60 ;

Step VII-B: Storage of the measurement resolution MA , the lateral measurement position LM , the lateral change in measurement position LMÄ and the distance related to the measurement position A. of the RAMAN sensor 21 during the second chemical-physical analysis by means of the storage unit 60 ;

Step VIII: correlating the measurement position-related results from the first chemical-physical analysis (XRF sensor 20th ) and the second chemical-physical analysis (RAMAN sensor 21 ) by means of the control 30th ;

Step IX: Visual display of the measurement position-related results from the first chemical-physical analysis (XRF sensor 20th ) and the second chemical-physical analysis (RAMAN sensor 21 ) by means of the display unit 50 .

The 4th shows a step sequence plan for the schematic sequence of a further embodiment of the method according to the invention with an XRF sensor 20th , RAMAN sensor 21 , LIBS sensor 22nd , HSI sensor 23 and RGB 3D sensor 24.

Step I: Determination of the position and orientation of the rock and / or soil sample 100 by means of the RGB-3D sensor 24 and determining a lateral measurement position LM and a lateral change in measurement position LMÄ of the XRF sensor 20th relative to the rock and / or soil sample 100 by means of the controller 30th ;

Step II: Determination of the surface geometry of the rock and / or soil sample 100 by means of the RGB-3D sensor 24 and determination of a measurement-position-related distance A. of the XRF sensor 20th relative to the rock and / or soil sample 100 by means of the controller 30th ;

Step III: Performing the first optical analysis using the HSI sensor 23 ; Step III-A: Storage of the measurement position-related results of the first optical analysis (HSI sensor 23 ) by means of the storage unit 60 ;

Step III-B: Storage of the measurement resolution MA , the lateral measurement position LM , the lateral change in measurement position LMÄ and the distance related to the measurement position A. of the HSI sensor 23 during the first optical analysis by means of the storage unit 60 ;

Step IV: segmentation of the rock and / or soil sample 100 in local sections 101 based on measurement position-related results from the first optical analysis (HSI sensor 23 ) by means of the control 30th ;

Step V: Determination of a lateral measurement position LM , a lateral change in measurement position LMÄ and a measurement position-related distance A. each of the XRF sensor 20th and the RAMAN sensor 21 relative to the rock and / or soil sample 100 and a measurement resolution MA each of the XRF sensor 20th and the RAMAN sensor 21 for the respective local section 101 ;

Step VI: Performing the first chemical-physical analysis using the XRF sensor 20th ;

Step VI- A. : Storage of the measurement position-related results of the first chemical-physical analysis (XRF sensor 20th ) by means of the storage unit 60 ;

Step VI-B: Storage of the measurement resolution MA , the lateral measurement position LM , the lateral change in measurement position LMÄ and the distance related to the measurement position A. of the XRF sensor 20th during the first chemical-physical analysis by means of the storage unit 60 ;

Step VII: Performing the second chemical-physical analysis using the RAMAN sensor 21 ;

Step VII- A. : Storage of the measurement position-related results of the second chemical-physical analysis (RAMAN sensor 21 ) by means of the storage unit 60 ;

Step VII-B: Storage of the measurement resolution MA , the lateral measurement position LM , the lateral change in measurement position LMÄ and the distance related to the measurement position A. of the RAMAN sensor 21 during the second chemical-physical analysis by means of the storage unit 60 ;

Step VIII: Carrying out the third chemical-physical analysis using the LIBS sensor 22nd ;

Step VIII- A. : Storage of the measurement position-related results of the second chemical-physical analysis (LIBS sensor 22nd ) by means of the storage unit 60 ; Step VIII-B: Storage of the measurement resolution MA , the lateral measurement position LM , the lateral change in measurement position LMÄ and the distance related to the measurement position A. of the LIBS sensor 22nd during the third chemical-physical analysis by means of the storage unit 60 ;

Step IX: correlating the measurement position-related results from the first chemical-physical analysis (XRF sensor 20th ) and the second chemical-physical analysis (RAMAN sensor 21 ) and the third chemical-physical analysis (LIBS sensor 22nd ) by means of the control 30th ;

step X : Visual display of the measurement position-related results from the first chemical-physical analysis (XRF sensor 20th ) and the second chemical-physical analysis (RAMAN sensor 21 ) and the third chemical-physical analysis (LIBS sensor 22nd ) by means of the display unit 50 .

The 5 shows a schematic representation of a mobile analysis system 1 . With the mobile analysis system shown, the method according to the invention is for analyzing heterogeneous rock and / or soil samples 100 feasible.

The analysis system includes an XRF sensor 20th , a RAMAN sensor 21 , a LIBS sensor 22nd , an HSI sensor 23 and an RGB 3D sensor 24. The sensors 20th , 21 , 22nd , 23 , 24 are on a three-axis guide unit 4th attached and thus by means of the three-axis guide unit 4th movable. The three-axis guide unit 4th a lateral guide 4a for moving the sensors 20th , 21 , 22nd , 23 , 24 along a first axis X , a longitudinal guide 4b for moving the sensors 20th , 21 , 22nd , 23 , 24 along a second axis Y as well as a vertical guide 4c for moving the sensors 20th , 21 , 22nd , 23 , 24 along a third axis Z on. By means of the cross guide 4a and longitudinal guide 4b can each have a lateral measurement position LM and a lateral measurement position change LMÄ can be set. By means of the vertical guide 4c can each have a measurement position-related distance A. can be set. Due to the three-axis guide unit, it is also possible, for example, to change the lateral measurement position LMÄ a first sensor 20th , 21 , 22nd , 23 , 24 through this or a second sensor 20th , 21 , 22nd , 23 , 24 to repeat.

The control 30th is with the three-axis guide unit 4th , every sensor 20th , 21 , 22nd , 23 , 24 , the storage unit 60 and the display unit 50 by means of signal connections 40 connected in terms of signaling. In addition, the storage unit is 60 directly, i.e. without the control being interposed 30th , with the three-axis guide unit 4th and the sensors 20th , 21 , 22nd , 23 , 24 by means of signal connections 40 connected in terms of signaling.

By means of the control 30th the measurement position-related results from the sensor-supported chemical-physical analyzes are correlated with each other in relation to the measurement position.

By means of the storage unit 60 become the respective lateral measurement position LM and respective lateral measurement position change LMÄ and the respective measurement position-related distance A. of the sensors 20th , 21 , 22nd , 23 , 24 relative to the rock and / or soil sample 100 and a measurement resolution MA of the sensors 20th , 21 , 22nd , 23 , 24 saved.

By means of the display unit designed as a monitor 50 the measurement position-related results from the sensor-based chemical-physical and / or sensor-based optical analyzes are displayed visually.

The rock and / or soil sample 100 is during the sensor-based chemical-physical and / or sensor-based optical analysis (s) using the on the measuring table 3 arranged recording 3a statically supported.

The 6th shows a schematic representation of a rock and / or soil sample designed as a drill core 100 . The rock and / or soil sample 100 is in local sections 101 segmented.

For the local sections 101 are each different lateral measurement positions LM and lateral measurement position changes LMÄ and measurement position related distances A. of the sensors 20th , 21 , 22nd , 23 , 24 relative to the rock and / or soil sample 100 and different measurement resolutions MA of the sensors 20th , 21 , 22nd , 23 , 24 has been determined.

List of reference symbols

1

Mobile analysis system

2

Vertical beam

3

Measuring table

3a

admission

4th

Three-axis guide unit

4a

Lateral guidance

4b

Longitudinal guide

4c

Vertical guide

20th

XRF sensor

21

RAMAN sensor

22nd

LIBS sensor

23

HSI sensor

24

RGB 3D sensor

30th

control

40

Signal connection

50

Display unit

60

Storage unit

100

Rock and / or soil sample

101

Local section of the rock and / or soil sample

A.

Distance related to the measurement position

LM

Lateral measurement position

LMÄ

Lateral change of measurement position

MA

Measurement resolution

X

First axis

Y

Second axis

Z

Third axis

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• US 8538697 B2 [0002]
• US 2016/0266275 A1 [0003]
• US 8234912 B2 [0004]
• WO 2009/101265 A1 [0005]
• WO 2013/180922 A1 [0005, 0014]
• DE 112013004743 T5 [0005]
• WO 2017/155450 A1 [0006]
• WO 2011/146014 A1 [0007]
• US 6628322 B1 [0008]

Claims (21)

A method for analyzing a heterogeneous rock and / or soil sample (100), preferably a drill core, wherein a first and a second sensor-supported, contactless and non-destructive chemical-physical analysis are correlated with one another by means of a control (30) in relation to measurement positions, characterized in that that the first sensor-based, non-contact and non-destructive chemical-physical analysis is carried out using an XRF sensor (20) and the second sensor-based, non-contact and non-destructive chemical-physical analysis is carried out using a RAMAN sensor (21). Procedure according to Claim 1 , characterized in that a third sensor-based and contactless chemical-physical analysis is correlated with the first and / or the second, in each case, sensor-based and contactless and non-destructive chemical-physical analysis by means of the controller (30) in relation to the measurement position, and the third sensor-based and contactless chemical -physical analysis is preferably carried out by means of a LIBS sensor (22). Method according to one of the preceding claims, characterized in that in the sensor-based chemical-physical analysis an elementary composition and / or structure of the rock and / or soil sample (100) or a sub-area of the rock and / or soil sample (100) qualitatively and is determined quantitatively. Method according to one of the preceding claims, characterized in that at least two of the sensor-based chemical-physical analyzes are correlated in relation to the measurement position in such a way that, for an evaluation of the rock and / or soil sample (100), the measurement-position-related results for a chemical-physical characteristic accurate sensor-based chemical-physical analysis can be used. Method according to one of the preceding claims, characterized in that at least two of the sensor-supported chemical-physical analyzes are correlated in relation to the measurement position in such a way that, on the basis of measurement-position-related results from a previous sensor-supported chemical-physical analysis, a segmentation of the rock and / or soil sample (100 ) in local sections (101) and for the respective local section (101) a lateral measurement position (LM) and / or a lateral measurement position change (LMÄ) and / or a measurement position-related distance (A) for a further sensor-based chemical-physical analysis used sensor (20, 21, 22) relative to the rock and / or soil sample (100) and / or a measurement resolution (MA) of this sensor (20, 21, 22) is determined. Method according to one of the preceding claims, characterized in that the rock and / or soil sample (100) is segmented into local sections (101) by means of a first sensor-supported optical analysis and a lateral measurement position (LM) for the respective local section (101) ) and / or a lateral measurement position change (LMÄ) and / or a measurement position-related distance (A) of the sensor (20, 21, 22) used for the respective sensor-based chemical-physical analysis relative to the rock and / or soil sample (100) and / or a measurement resolution (MA) of this sensor (20, 21, 22) is determined. Procedure according to Claim 6 , characterized in that the segmentation takes place on the basis of a geometry, color and / or surface property of the rock and / or soil sample (100). Method according to one of the Claims 6 or 7th , characterized in that the first sensor-based optical analysis comprises a 3D measurement, preferably using an RGB-3D sensor (24), and / or hyperspectral imaging, preferably using an HSI sensor (23). Method according to one of the Claims 5 to 8th , characterized in that the measurement resolution (MA) and / or the lateral measurement position (LM) and / or the lateral measurement position change (LMÄ) and / or the measurement position-related distance (A) of the used for the respective or the further sensor-based chemical-physical analysis Sensor (20, 21, 22) depends on the fact that a homogeneous or heterogeneous local section (101) is determined during the first sensor-supported optical analysis or the preceding sensor-supported chemical-physical analysis. Method according to one of the preceding claims, characterized in that a position and / or orientation of the rock and / or soil sample (100) is determined by means of a second sensor-supported optical analysis and thereby a lateral measurement position (LM) and / or a lateral measurement position change (LMÄ ) of the sensor (20, 21, 22) used for the respective sensor-based chemical-physical analysis is determined relative to the rock and / or soil sample (100). Procedure according to Claim 10 , characterized in that by means of the second sensor-based optical analysis a Surface geometry of the rock and / or soil sample (100) is determined and a measurement position-related distance (A) of the sensor (20, 21, 22) used for the respective sensor-based chemical-physical analysis relative to the rock and / or soil sample (100) is determined becomes. Method according to one of the Claims 10 or 11 , characterized in that the second sensor-supported optical analysis comprises a 3D measurement, preferably by means of the RGB-3D sensor (24). Procedure according to Claim 5 to 12th , characterized in that the lateral measurement position (LM) along two axes of a coordinate system and the measurement position-related distance (A) along a third axis of the coordinate system, preferably by means of a three-axis guide unit (4), can be set independently of one another or axially superimposed. Method according to one of the Claims 5 to 13th , characterized in that the respective measurement resolution (MA) and / or the respective lateral measurement position (LM) and / or the respective lateral measurement position change (LMÄ) and / or the respective measurement position-related distance (A) of a sensor (20, 21, 22, 23, 24) is stored so that another sensor (20, 21, 22, 23, 24) in each case at the same lateral measurement position (LM) and / or according to the same lateral measurement position change (LMÄ) and / or with the same measurement position-related distance (A) can be arranged relative to the rock and / or soil sample (100) and / or set with the same measurement resolution (MA). Method according to one of the preceding claims, characterized in that two sensor-based chemical-physical analyzes or one sensor-based chemical-physical and one sensor-based optical analysis, preferably by means of the HSI sensor (23) and the XRF sensor (20), or two sensor-based optical analyzes of the rock and / or soil sample (100) can be carried out at the same time. Method according to one of the preceding claims, characterized in that the rock and / or soil sample (100) is stored statically during the sensor-supported chemical-physical and / or sensor-supported optical analysis. Method according to one of the preceding claims, characterized in that the measurement position-related results from the sensor-supported chemical-physical and / or the sensor-supported optical analysis are visually displayed after they have been correlated with one another. Mobile analysis system (1) with which a method for analyzing heterogeneous rock and / or soil samples (100) can be carried out, comprising: • Holder (3a) for static storage of a rock and / or soil sample (100) • at least a first and a second sensor (20, 21, 22) for a chemical-physical analysis • First three-axis guide unit (4) for the first sensor (20, 21, 22) • Second three-axis guide unit (4) for the second sensor (20, 21, 22) • Control (30) which is suitable for correlating the first and second, in each case sensor-supported, chemical-physical analysis with one another in relation to the measurement position • Storage unit (60) which is suitable for storing a lateral measurement position (LM) and / or a lateral measurement position change (LMÄ) and / or a measurement position-related distance (A) of the sensors (20, 21, 22, 23, 24) relative to the rock - and / or soil sample (100) and / or a measurement resolution (MA) of the sensors (20, 21, 22, 23, 24) to be stored • Display unit (50), preferably a monitor, for the visual display of measurement position-related results Analysis system (1) according to Claim 18 , characterized in that one of the sensors for a chemical-physical analysis is an XRF sensor (20) or a RAMAN sensor (21) or a LIBS sensor (22). Analysis system (1) according to Claim 18 or 19th , characterized in that it comprises an RGB-3D sensor (24) and / or an HSI sensor (23). Analysis system (1) according to one of the Claims 18 to 20th , characterized in that all sensors (20, 21, 22, 23, 24) are arranged on a three-axis guide unit (4).

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