EP2580563A2 - Method for low-vibration optical force measurement, in particular at high temperatures - Google Patents

Abstract

The invention relates to a method for optical force measurement, in which an elastically deformable and/or an elastically deforming region (2) of a solid body (1) is subjected, owing to the influence of a force, to a change in its geometry, the change in geometry of the region (2) that is effected owing to the influence of the force is optically acquired and the force effecting the change in geometry is calculated from the optically acquired change in geometry using a predetermined, preferably bijective force-geometry change relationship. The invention likewise relates to an arrangement for carrying out this method.

Description

Method for low-vibration optical force measurement, especially at high temperatures

Field of the invention:

The present invention relates to a method of optical force measurement, for example in the field of high-speed tests and / or at high or low temperatures. In this context, a high-speed test is understood to mean an experiment in which a material sample is subjected to a rapid, sudden load (rapid dynamic load) which leads to a change in geometry, in particular a change in length, of the material sample. The invention also relates to an arrangement which is designed to carry out a method for optical force measurement. Prior art and disadvantages of known solutions:

In general, for the characterization of solids (ie material samples) and for obtaining material characteristics and / or material characteristics "(for example: raft extension or force compression curves and / or derived therefrom technical and true stress-strain curves or characteristics such as yield strength and tensile strength) In the case of static or sufficiently slow tests, such as, for example, in standardized tensile tests, the force measurement is carried out with a load cell of the testing machine used for the corresponding tensile test.

However, in the automotive industry, for example, characteristic values and flow curves for describing the deformation and deformation are used as input data for vehicle crash simulations for the materials used

Failure behavior at crash relevant external load speeds up to about 20 m / s needed, which cause locally high strain rates up to about 500 s ^_1 in the loaded components / components. In the case of corresponding high-speed tests with material samples for determining the material properties under crash loads, however, the following difficulties occur: The load cells of the testing machine react either too slowly or have too low amplifier bandwidths in order to be able to detect the rapid processes. In addition, the force measuring cells are stimulated by the necessary rapid, usually sudden force introduction into the solid to be tested due to inertial forces to strong vibrations. Due to these oscillations strongly oscillating "global" force signals arise from which the actual material behavior can no longer be reasonably deduced.

Recommendations are already known from the prior art as to how, even with high-speed tests, a force measurement can take place: Thus, a "quasi-local" force measurement with special

Force measuring elements, which provide less vibration than the "global" force measurement, take place (see, for example, EP 1 466 157 B1). An even more accurate

Force measurement can be achieved with strain gauges: In this "local" force measurement, strain gauges in the dynamometer part of the

testing solid or material samples used, the strain signal in static preliminary tests in

Compared to a conventional force measurement can be calibrated with the load cell.

The latter measurement technique is at high strain rates of the current guidelines {W. Böhme: FAT guideline "Dynamic Material Characteristics for Crash Simulation", Journal Material Testing,

Materials Testing, Carl Hanser Verlag, Munich, Vol. 50 (4), Ξ. 199-205, 2008; Stahl-Eisen-Prüfblatt 1230 "Determination of mechanical properties of sheet materials at high strain rates in high-speed tensile tests", Stahlinstitut VDEh, Dusseldorf, first edition, 2007; DIN EN ISO 26203-2: 2009) is recommended as the best option.

In particular, the latter measurement technique is very expensive because of the instrumentation of each material sample ^' , each with a strain gauge on the front and back and the required calibration. In addition, a basic requirement is that the modulus of elasticity of the material to be investigated is not dependent on the strain rate, so that the application z. B. in plastics is not directly possible (this restriction does not apply to the method of EP 1 466 157 Bl). In addition, the aforementioned measurement techniques are based on the use of strain gauges which are to be applied to the material robe (or to the special force measuring element). Thus, the range of application is limited to the field of application of strain gauges, ie for conventional glued foil expansion strips approximately to a temperature range of -60 ° C to +200 ° C. {For experiments at higher temperatures, it is basically possible, for example in the case of metallic materials, to apply high-temperature strain gauges to any material sample by soldering or welding, but this is a very expensive and expensive solution.)

Object of the invention:

Starting from the prior art, it is therefore an object of the present invention to provide a method for optical force measurement (which can be used in particular in the field of high-speed experiments), which allows a force acting on a solid (material sample) force with high Accuracy and in a wide range of applications (in particular: temperature range, but possibly also pressure range) to determine. In addition, this force measuring method should, in particular, also be suitable for determining the time-dependent force curve with high precision under fast, dynamic loads.

The object of the invention is, moreover, an arrangement with which the aforementioned optical force measuring procedure can be carried out.

Suggested solution:

The present object is achieved by a method for optical force measurement according to claim 1 and by a corresponding arrangement according to claim 15. Advantageous embodiments can be found in each of the dependent claims.

Hereinafter, the present invention will be described first in general, then by means of an embodiment. The following description of the force measuring method is carried out primarily on a method for carrying out a high-speed test and the geometry changes in the course of such an experiment on a solid, for example in the form of changes in length. However, the present invention can also be used outside the range of high-speed experiments, with the specific geometry change which is evaluated according to the invention being determined in each case from the type of test used (see below).

Also, the individual features shown in a particular combination in the concrete embodiment of the arrangement and of the performed single encryption must be implemented method steps in the present invention is not in the form shown, but may be otherwise reali ^¬ Siert within the specified by the claims scope In particular, individual ones of the method steps and / or features shown can also be designed differently or omitted. Furthermore Of course, other combinations of the described individual steps and / or individual features within the scope of the present invention can be realized with one another.

Basic idea of the present invention:

This idea is based on the change in the geometry of this solid in this area resulting from the action of a force in an elastically deformable region of a solid

visually detect and calculate from the thus detected change in geometry based on a predetermined force-geometry change Zusarnmenhang the force causing the change in geometry. The predetermined (preferably one-to-one) force-geometry change relationship may in particular be Hooke's law. In principle, however, other, e.g. Non-linear relationships for determining the applied force in the context of the present invention evaluable.

Thus, the following behavior of material samples can be exploited with the invention: With small technical tensions until the so-called yield strength is reached, the strain in the material sample is reversible, and the technical tension depends linearly on the elongation; the deformation of the material sample is thus elastic (Hooke's law: σ = E xz, where σ is the technical strain, ε the strain and E the modulus of elasticity). At stresses above the yield strength, Hooke's law loses its validity, causing plastic deformation of the material sample. However, as described in more detail below, the elastic range may be due to the hooke The force-geometry change relationship described above is exploited, from an expansion (after suitable calibration or determination of the modulus of elasticity) the associated technical tension and from this with the corresponding output cross section at the measuring point on the sample, the corresponding force which causes this strain determine. This is done as described above according to the invention by optical means.

The basic idea of the present invention is therefore to optically record and evaluate a change in geometry in an elastic sample section (in particular: a strain measurement in a dynamometer part of the specimen that deforms exclusively elastically). The optical detection can be especially useful in high speed trials e.g. mithälfe a high-speed camera with high spatial and temporal resolution and the evaluation with a corresponding Bildanalyseso tware, as described in detail below, be performed with high accuracy.

Advantageous developments of this basic idea in the context of the present invention:

In a first advantageous embodiment, a reversible change in length, in particular an extension or a shortening, of the elastic region is detected optically. The predetermined force-geometry change relationship can thus be a relationship between a force effect and a reversible change in length in the elastic region caused by this force effect (eg Hooke's law). However, it is not necessary to record changes in length that table acquisition can also z. B. in high-speed tests (such as shear tests) are used, which lead to a rotation, distortion and / or shear in the elastically deforming area, which can then be correspondingly optically recorded and evaluated.

Advantageously, over a predefined time interval, the momentary state of the geometry of the elastic region caused in each case by a temporally varying acting force can be detected optically. The instantaneous force acting on this instantaneous state of the geometry can then be calculated from the current geometry state by means of the predetermined force-geometry change relationship. According to the invention, a determination of the time-dependent force signal is thus possible.

For example, in the elastic region, at least two markings can be applied at a distance from one another. Alternatively, however, it is also possible to use two predetermined structures (eg projections or trenches or also protruding surface textures in this area) arranged at a distance from one another as markings. These markers are then optically imaged at different acting forces. Positions and / or distances of these markings are evaluated in these different geometrical states, such as, for example, lengths of the elastic region reflecting optical images, ie positions and / or distances of these markings in the individual optical images are determined and for calculating changes in geometry in the elastic region evaluated. The solid (material sample) can be a

Inelastisch deformable test area and have a material fit associated with and / or integrally formed with the test area dynamometer area. The dynamometer area is then the area of the solid body which deforms purely elastically under the action of force and which is optically detected according to the invention.

Thus, according to the invention, two (or even more) temperature-resistant markings can be applied in the dynamometer part of the sample. Depending on the optical evaluation method used (image analysis method), these markings can be lines, points, circles or crosses, or else contain stochastically distributed speckle patterns, as used, for example, in gray scale correlation analyzes which can be used as optical evaluation methods.

The width of the dynamometer range is generally much greater than the width of the test area described above, in order to obtain exclusively linear-elastic deformations in the dynamometer area until the sample breaks in the test area.

Video cameras can be used for recording, high-speed video cameras in particular can be used as optical measuring devices, but alternatively optical extensometers can also be used. In the case of tensile tests (in particular: high-speed tensile tests), an elongation as a function of the loading time can thus be recorded according to the invention. Extension curves can be created from those on ^¬ drawings after exposure, the time-dependent Verlan- represent the load interval. It is essential that the corresponding geometric changes in high local-. and / or temporal resolution; This is especially with the use of high-speed video cameras with

Image acquisition rates of at least 10,000 images per second, preferably with at least 100,000 images per second ensured, usually at the same time a sufficiently large spatial resolution or a sufficiently large number of pixels (pixels) is required (eg 100 pixels in the measuring direction) to achieve sufficient measurement accuracy. Other optical measuring methods, such as, for example, laser-optical methods, are also suitable with adequate spatial and temporal resolution.

Thus, according to the invention, the forces caused by a dynamic and / or rapid loading of the material sample (eg with external loading speeds up to about 100 m / s) can be locally measured, during which load optical images of the elastic dynamometer area (that is, for example, the Markers in this area} can be generated by means of a camera, which can then be evaluated by means of an image analysis procedure, such as a gray value correlation analysis, on the basis of which evaluation the force which changes the geometry in the elastic range is calculated, as a rule using a calibration factor to be determined with at least one quasi-static preliminary test.

The dynamic and / or rapid loads may take the form of high-speed tests, in particular high-speed tensile tests, notched tensile tests, shearing tests and / or compression tests. be brought. The test equipment that can be used for this purpose, such as high-speed machines or

Impact devices are basically known to the person skilled in the art. In quasistatic preliminary tests or in preliminary tests at moderate loading speeds (about <0.1 m / s), the geometry change in the dynamometer part against previously used force on at least one comparably instrumented and loaded material sample by means of conventional force measurement (for example with a load cell of the test device used) calibrated, ie a static calibration factor determined, it can then be determined in the actual experiments on the basis of the recorded optical images of the time-dependent ("local") force curve. The calibration is done in the elastic dynamometer part of the sample. As an alternative to the determination of the calibration ^factor , the calculation of the calibration ^factor is also possible with knowledge or assuming a constant modulus of elasticity using Hooke's law.

The calibration (or the determination of the predetermined force-geometry change relationship by static or quasi-static load of the solid) is advantageously carried out at external load speeds of <0.1 m / s, Example: In high-speed tensile test, the positions of the optical The selected markings can be evaluated with image analysis methods, from this the image of the time course of the local extension in the dynamometer part dL _D (t) and the previously determined calibration factor Λ can be used to determine the desired local force curve F (t) = Λ x dL _D (t) who- the. From the optically detected as described above extension curve dL _D (t) in the elastic range (for pressure tests: compression curve) is thus obtained the required for further analysis material characterization time-dependent Kra ^'ftsignal F (t). (Since this force acts on the test cross-section A in the thinner test part of the specimen, the curve of the technical tension in the test specimen is o (t) = F (t) / A ") Because of the local (optical) measurement in the dynamometer range of the invention Solid body is obtained a particularly low-vibration force signal.

In addition to determining a low-vibration force signal, the present invention has the particular advantage that the method can also be carried out at temperatures of the solid which deviate greatly from the room temperature (for example, significantly above 200 ° C.). Of course that is. but also at room temperature, d. H. at 20 ° C, can be used.

In order to additionally detect the deformation behavior of the thinner test part of the sample until it breaks during the load, the change in the distance of the markings applied in the test part can be recorded with an optical measuring device.

In order to arrive at a comprehensive material characterization of the material sample under fast, dynamic loads (in particular in high-speed tests), a measurement of a change in geometry, in particular an extension dLp (t) or compression, can additionally be carried out in the test area of the sample. This measurement in the test area of the be advantageously also visually, that is z. B. using high-speed cameras, done. The force measurement according to the invention can thus be coupled with an extension or compression measurement in the test area of the sample in order to enable a comprehensive material characterization, for example in order to obtain a force extension curve. This can be realized, in particular, by optically detecting and evaluating not only the elastic region of the sample, but at the same time and preferably with the same high-speed video recording and also the time profile of the technical strain in the test region of FIG

Sample is optically detected and evaluated by the determined extension dL _P {t) is related to the test length L ₀ : ε (t) - dLp (t) / L ₀ . For this purpose, appropriate markings (ie spaced apart from one another by L ₀ ) in the test area of the sample are also to be applied or existing markings evaluated.

Advantageously, a tapered, non-reversibly deforming test region of the solid body (which is subjected to the same force as the elastic region of this test specimen) is thus also detected by measurement, wherein this detection advantageously also takes place optically. Then with a single high-speed video film both the force curve or the voltage curve o (t) and the strain curve in the test area of the sample ε (t) can be measured simultaneously, so that, for example, the technical stress-strain curves σ (ε) to a crash-relevant material characterization and as input data for

Crash calculations can be determined (if necessary, also the true stress-strain curves on conversion assuming volume constancy in the region of the uniform mass). The force is related to the output cross-section in the test area of the sample and the extension to the initial measuring length in the test area of the sample. With high-speed cameras with more than 100,000 images per second and a sufficient number of pixels, this allows a sufficient number of images even at high, crash-relevant strain rates or at correspondingly high, crash-like loading speeds, for example in the range of 20 m / s (possibly even beyond) gain per second as bases for the evaluation of reliable dynamic stress-strain curves. The inventive method is applicable to flat tensile and round tensile specimens; depending on the sample size, the markings and the optical paths should be adapted to the situation.

Since samples taken from semi-finished products or components are often slightly curved, bending parts in the measurement and different results can occur, depending on which sample side the measurement is performed. Accordingly, in a further advantageous variant, it is advisable to carry out the optical detection of the change in geometry of the elastic region and / or the test region of the sample on both sides of the sample.

For this purpose, either two high-speed cameras can be used or only one high-speed camera, for example using mirrors of optical quality. In the latter case, the different sides of the material sample are imaged onto one and the same high-speed camera via an imaging optics which preferably comprises at least two mirrors. Finally, an arrangement according to the invention for carrying out the method according to the invention comprises a test device for dynamically loading the material sample and an optical detection and evaluation device preferably having at least one camera {high-speed camera) for performing the optical detection and the subsequent calculations.

Advantages of the invention:

Compared to the methods of force measurement known from the prior art, the method according to the present invention offers the following advantages in particular:

^■ The process can also be used at high and low temperatures (especially at temperatures above 200 ° C).

^■ The method provides inertia-free force measurement due to the "local" optical strain determination in the dynamometer part of the sample, allowing low-vibration force measurements even at high load speeds.

^■ Will also be the measurement of the test area

optically carried out, a simultaneous measurement of the force and the Prüfteildehnung directly on the sample with a single high-speed video recording takes place. At the same time, the procedure is also possible. Insert on both sides of the sample, using appropriately aligned optical grade mirrors become .

In the method according to the invention, therefore, no force measuring cell (except, if necessary, for calibration in a static preliminary test) is required and the effort for applying markings or speckle patterns to the sample is much less than the effort for applying strain gauges.

Exemplary embodiments:

In the following, the present invention will be described in detail with reference to an exemplary embodiment (FIGS. 1 and 2) as well as a variant thereof (FIG. 3) on the basis of tensile tests.

1 shows a material sample usable according to the invention together with applied markings.

2 shows the principle of the scanning of this material sample by a high-speed video camera and the relationships that can be determined from the evaluation of the scanned image data.

3 shows a variant of the method shown in FIGS. 1 and 2, in which a double-sided sample scanning takes place.

FIG. 1 shows a material sample 1 suitable for carrying out a method according to the invention, here for example made of aluminum. "The material sample 1 is made in one piece and as an elongate sample body. forms and has at its two opposite longitudinal ends la and lb two thickened sections, which are designed for clamping in a high-speed ZugprüfVorrichtung. The upper end 1a is designed for clamping into the fixed Probeneinspannung 8a (Figure 2) of the test apparatus (fixed clamping area la), the down here shown, opposite end of the sample body 1 (accelerated clamping area lb of the sample) for clamping in the accelerated sample clamping 8b of the test device.

Between the two ends la, lb there are two further regions of the material sample 1, the dynamometer region 2 formed with the same cross-section as the fixed clamping region 1a and immediately adjacent to the latter, and the material on it (ie on the opposite side of the stationary clamping region 1a) The test section of the material sample 1 is immediately adjacent to the dynamometer section 2). All the sections 1a, 2, 3 and 1b of the sample 1 are formed here together as a one-piece body, that is to say connected in a material-locking manner. At the end of the test part 3 facing away from the dynamometer region, the accelerated clamping region 1b of the sample thus follows, which in turn is formed with the same cross section as the regions 1a, 2 of the sample. In contrast, the test area 3 tapers toward the middle between the two adjacent areas 1b, 2, thus having a significantly reduced cross section there. Due to this significantly reduced cross section, the test area 3 of the sample can also be deformed beyond reaching the yield point (plastic deformation), without it being in the dynamometer area

2 comes to a plastic deformation of the sample. In other words, even with a plastic deformation of the sample in the test area 3, the elastic deformation of the sample in the dynamometer area is maintained. FIG. 1 shows two line-shaped markings 4a, 4b, which are arranged at a distance from one another along the longitudinal axis of the sample 1 in the dynamometer region 2 of the sample. Since the sample 1 deforms purely elastically in the dynamometer region 2, these two markings 4 a, 4 b or the latter can be modified

Zugbelastung changing positions, in particular whose changing distance to be used, as described above, according to the invention optically to detect the length or geometry change in area 2 and from the force-length change

Context of calculating the force sought.

Likewise, two further marks 5a, 5b are on the same side of the sample, but centrally in the tapering section of the test area 3 of the sample

spaced from each other and applied along the longitudinal axis of the sample 1 on the sample body. These two markings 5a, 5b are also optically detected for further optical strain determination (extension measurement) in the test area 3 of the sample.

In order to detect and evaluate the changes in the positions and / or the distances of the markers 4a, 4b, 5a, 5b, a high-speed camera is used

6 (not shown in FIG. 1, compare FIG. 2) and aligned with the sample 1 such that their image field covers both the dynamometer region 2 (ie the markings 4a, 4b) and the test region 3 (ie the markings 5a, 5b) As described above, the highest possible frame rate {> 10,000 images per second) with a sufficiently high number of pixels recorded high-speed video film then using an image analysis method, or evaluated when using speckle markings on the basis of gray value correlation analysis.

The grayscale correlation analysis, which can be advantageously used, in particular for speckle markings and described here by way of example, as an optical measuring method, with which local changes, for example one

Surface, which were caused by mechanical stress, can be traced, stored and evaluated qualitatively and quantitatively on the basis of the gray scale distribution of imprints of the surface to different states of stress, is known to the person skilled in the art: For (digitized) images of different states Using an algorithm based on the application of the cross-correlation function, determine a shift field that has occurred between the states or images.

As a result of the correlation, a graphic image of the displacement field is obtained, represented as a vector image or as an overlay grating; an associated protocol provides quantitative information for each evaluated point {positions, displacements and maximum correlation coefficients). The data of the protocol can u. a. be used for the quantitative determination of components of the distortion sensor, from which the desired material properties such as the strain can be derived.

In the example presented, the longitudinal extent L _{k of} the dynamometer section 2 is about 30 mm and the

Cross-sectional dimension b _{k of} this range about 35 mm. The distance of the markers 4a, 4b is for example 20 mm. The distance a of the two markings 5a, 5b in Test area 3 is 20 minutes here. The total length L _{t of} the sample here is about 150 mm.

FIG. 1 thus shows how according to the invention a

Flat tensile specimen for high-speed tensile tests on the basis of applied in Dynamometerteil 2 markers 4a, 4b, used, so can be used for local optical force measurement, in which case the strain measurement in the test area 3 of the sample 1 is optically.

Figure 2 outlines an arrangement according to the invention, which is designed for performing a method according to the invention ^¬ ahead, so for example, for optical imaging outlined in Figure 1. The arrangement comprises at first a testing device, which is merely indicated here, with a fixed sample clamping 8a, in which the section 1a of the sample shown in FIG. 1 is fixed almost immovably (FIG. 2, upper center). In addition, the testing device comprises an accelerated sample clamping 8b (FIG. 2, middle bottom), which is also merely indicated here, in which the section 1b of the sample 1 is movably fixed and where the dynamic loads are introduced by a suitable loading device.

Furthermore, the arrangement comprises a high-speed video camera 6, which is designed and arranged (possibly with additional optics not described in detail here), that both the test area 3 and the dynamometer area 2 of the sample 1 simultaneously and with very high time resolution or frame rate with sufficient number of pixels can be optically detected. The arrangement finally includes one with the high speed video camera For the bidirectional data exchange associated evaluation device 9 {for example, a computer system), with which the above-described Grauwertkorrelationsana- analysis of the camera 6 detected positions 4a, 4b, 5a, 5b is possible. Elements 6 and 9 of

Form test device (possibly together with other optical elements used for multilateral imaging 7a, 7b, see Figure 3), the detection and evaluation ^¬ device of the arrangement.

As Figure 2 shows the top right, can be with not described in detail here image analysis methods, if necessary., The gray value correlation analysis, from the optically detected positions of the marks 4a, 4b, the modification of the industrial tensile stress o ^~ {t) determined during tensile loading with high temporal resolution , Also, the marks can be recorded on the basis of the individual camera images a ^¬ positions 5a, 5b with image analysis methods, if necessary. With the gray value of correlation analysis, the time

Change in the strain ε (t) of the material sample 1 in the test area 3 with high temporal resolution

bebestimmen. FIG. 2 at the bottom right then outlines the stress-strain curve σ (ε) obtained from these two curves a (t) and ε (t).

FIG. 2 thus shows the inventive principle of measurement technology for high-speed tensile tests with low-vibration local optical force and strain measurement.

FIG. 3 shows a variant of the present invention in which the determination of the aforementioned quantities ε, σ takes place on two opposite sides of the sample 1. The procedure and arrangement are basically the same as in FIGS. 1 and 2 described below, so that only the differences are described below.

In order to be able to determine both elongation values ε and technical tensile stress values σ on two opposite sides of the sample 1, respective mirror arrangements 7a, 7b are arranged on these two sides of the sample, which are aligned so that from both opposite sides of the sample in each case a test area and a dynamometer area of the sample can be detected by the single high-speed camera 6. Thus, the test area and the overlying dynamometer area of the first side Sl of the sample 1 are imaged via the mirror arrangement 7a into the receiving area of the camera 6 and the test area together with the adjacent dynamometer area of the opposite, second sample side S2 via the mirror arrangement 7b. The image must be made in such a way that the two opposite sides of the sample are imaged onto separate image sections of the image acquisition unit of the camera 6 so that the position of the individual markings can be separated during the evaluation. With sufficient agreement of the results of both sides (within about ± 10%) the signals can be averaged and used as a result. If there are greater deviations of both signals, the cause (for example, superimposed bending parts) must be located and corrected.

FIG. 3 thus shows an arrangement according to the invention for a two-sided optical force and strain measurement in high-speed tensile tests, with the aid of which bending parts with only one high-speed camera can also be detected.

Claims

claims

Method for optical force measurement, wherein an elastically deformable and / or an elastically deforming region (2) of a solid (1) is subjected to a change of its geometry by the action of a force, wherein the change of the geometry of the region caused by the action of the force ( 2) is optically detected and wherein the change in the geometry causing force is calculated on the basis of a predetermined, preferably a unique force-geometry change relationship from the optically detected change in geometry.

Method for optical force measurement ^' according to the preceding claim, characterized in that the optically detected change in geometry is a reversible change in length, in particular an extension or shortening, of the region (2) and / or that the predetermined force-geometry change relationship is a relationship between a Force and a force caused by this effect, reversible change in length of the elastically deformable and / or elastically deforming area {2) and / or the Hooke's Law corresponds, or the optically detected geometry change is a reversible twist, distortion and / or shear of the region (2).

Method for the optical force measurement according to one of the preceding claims, characterized in that over a predefined time interval of a temporally varying, acting force respectively caused instantaneous state of the geometry of the area (2) is optically detected and that each of these instantaneous state of the geometry causing currently acting force is calculated on the basis of the predetermined force-geometry change relationship from the optically detected instantaneous state of the geometry (calculation of the time-dependent force signal}.

Optical force measurement method according to one of the preceding claims, characterized in that the optical detection is carried out by arranging in the region (2) at least two markings (4a, 4b) spaced from one another or by at least two spaced-apart structures of the region {2} be used as such markers (4a, 4b) by these markers {4a, 4b) are each optically imaged at different acting forces and by in such various geometric states, in particular lengths of the region (2) of the solid (1) reflecting optical Figures Positions and / or distances of these marks (4a, 4b) are used to calculate a force effecting a change in the geometry of the solid (1).

Method for the optical force measurement according to one of the preceding claims, characterized in that the solid body (1) is a material sample having a test area (3) and elastically deformable and / or deforming area (2) one with this test area (3) material fit connected and / or integrally formed Dynamometerbereich, wherein the Dynamometerbereich is formed so that ^' under the action of the force is purely elastically deformable and / or deforms purely elastic, and wherein the Dynamometerbereich is optically detected, preferably optically imaged.

Method for optical force measurement according to one of the preceding claims, characterized in that the optical detection and / or imaging by means of a camera (6), in particular a high speed camera with a Bildauf rate of at least 10,000 images / s, preferably at least 100,000 images / s , is performed and / or that the optical detection by means of a laser optical method and / or an optical extensometer, in particular a Laser extensometer, is performed.

Method for the optical force measurement according to one of the preceding claims, characterized in that optical images of the elastically deformable and / or elastically deforming region (2), in particular of in this region (2) mounted markings (4a, 4b) are generated, preferably be generated by means of a camera (6), and evaluated by means of an image analysis method, in particular a gray value correlation analysis, to calculate the force causing the change of the geometry of the solid (1) and / or that the marks (4a, 4b) lines, points, circles , Crosses and / or stochastically distributed patterns, preferably speckle patterns, are.

Method for the optical force measurement according to one of the preceding claims, characterized in that the action of the force by a dynamic, rapid loading of the solid (1), in particular by loading the solid (1) with an external load speed of greater than 1 m / s, preferably greater than 10 m / s, preferably in the range of 10 m / s to 100 m / s, is realized and / or realized by the solid (1) a high-speed test, in particular a high-speed tensile test, a Kerbzugversuch, a shear attempt and / or a pressure test is suspended.

Method for the optical force measurement according to one of the preceding claims, characterized in that the predetermined force-geometry change context by a static or quasistatic load on the solid body (1), in particular by loading the solid (1) with an external load speed of less than 0, 2 m / s, preferably of less than 0.05 m / s, determined with different sized forces and by determining the respectively associated change in its geometry.

Optical force measurement method according to one of the preceding claims, characterized in that the method is carried out at room temperature or at a temperature of the solid (1) of above +200 ° C, in particular above +400 ° C, and / or that the action of the Force occurs and the solid state (1) is formed so that the region (2) of the solid body (1) deforms purely elastic and completely reversible.

Optical force measurement method according to one of the preceding claims, characterized in that a further region (3) of the solid (1), preferably a tapered test region of the solid (1), is likewise subjected to the action of this force and that deformation caused by this force, in particular stretching, lengthening or shortening, of the further area (3) is detected.

A method for optical force measurement according to the preceding claim, characterized in that the further region (3) is formed and formed from ^¬ that he under the influence of this force non-elastic, non-reversible deformed, in particular stretches, lengthened or shortened , and / or that the deformation of the further area {3) is detected optically, in particular in the same way and / or with one and the same camera (6} as in the elastically deformable

and / or elastically deforming region (2) is detected optically, or is detected by means of a strain gauge.

Method for optical force measurement according to one of the two preceding claims, characterized in that on the basis of the detection of the elastically deformable and / or elastically deforming region (2) and the detection of the further region (3), solid-specific characteristics and / or flow curves, especially for the description exercise of the Forfeiture and / or

 Failure behavior suitable characteristics and / or flow curves, and / or stress-strain curves of the solid (1) can be determined.

Method for optical force measurement according to one of the preceding claims, characterized in that on two different sides (Sl, Ξ2), in particular on two opposite sides, of the solid body (1) one by the action of a force, preferably one and the same force, caused change in the geometry of an elastically deformable and / or elastically deforming region (2) is optically detected, wherein preferably the different sides (Sl, S2) via a preferably at least two mirrors {7a, 7b) comprehensive imaging optics on a single camera (6 ), in particular a high-speed camera, are imaged or preferably wherein the different sides (Sl, S2) each on a separate camera, in particular in each case a separate Hochgeschwindig keitskamera be mapped.

Arrangement designed to carry out a method for optical force measurement according to one of the preceding claims, comprising a test device (8a, 8b) for dynamically loading the material sample, in particular a device for carrying out high-speed tests, and a preferably at least one camera (6), in particular at least one high-speed camera having, designed to perform the optical detection and the calculation and arranged optical detection and evaluation device (6, 7a, 7b, 9).