DE10112986A1 - Testing device, especially for testing the deformation behavior of geomaterials and geosynthetics, is designed so that pure tensile and shear tests can be applied independently using the same apparatus - Google Patents

Abstract

Samples (7b, 8b) of the material to be tested are placed in upper (7) and lower (8) shear frames, which can be moved freely in a vertical direction. Vertical loading of the upper and lower frames is applied using upper and lower loading units that act on upper (1) and lower (2) loading frames. A shearing force is applied by horizontal displacement of the upper shear frame. Upper and lower shear frames are loaded such that on the free outer edges of the material being tested both in vertical and horizontal directions pure kinematic border conditions apply.

Description

Testing device for examining the interaction - in particular for testing the deformation behavior tens - of geomaterials, geosynthetics and composite systems made of geomaterials and Geosynthetics, with integrated pull-out test facility.

Geosynthetics laid in the ground have properties that increase their load-bearing capacity and stability. These properties are based on the power transmission from the surrounding filling floor into the tensile reinforcements made of geosynthetics. Power is transmitted by Rei Exercise, interlocking and / or adhesion between reinforcement and filling floor. To the positive To be able to use the properties of geosynthetics, the interaction between between the geosynthetics laid in the ground and the adjacent earth material become.

Geotechnics are used to study the interface behavior between geomateria Lines and / or geosynthetics frame clippers with a minimum installation dimension of 300 mm × 300 mm and toroidal shearers used. Pull-out tests and tipping tests are also common Lich.

With the classic frame shearers, the test specimens are placed in one in the horizontal two-part frame installed. The consolidation is carried out one-dimensionally on one normal stress applied to the upper test specimen. The shear area is under constant Nor Color stress due to relative displacement between a held and a displaceable Chen part generated.

In the known devices, it is disadvantageous that the between by the relative displacement The side friction mobilized between the shaving box and the test specimen was not completely produced can be reduced.

A major disadvantage of conventional frame shearers is that the geosynthetic measurement samples embedded between two layers of soil are not exactly in the shear plane due to the normal tension applied on one side; rather, the geotextiles are indented into the lower half of the shear box [TAKASUMI, D. L ET. AL. ( 1991 ): Soil-Geosynthetics Interface Strength Characteristics: A Review of State-of-the-Art Testing Procedures. Geosynthetics' 97 Conference Atlanta, USA, pp. 87-100]. In addition, the shear gap is rarely demanded exactly during the test.

In the conventional frame shear devices, the shear force can not be free of tilting moment largely into the shear plane. Another disadvantage of these facilities is that that the compaction of the soil in the shear frame - unfavorable - on the bearings or on a external built-in table, a lifting device for lifting the heavy shear boxes freely is needed.

The invention has for its object to develop a test device with which the Grenzflä behavior - in particular the deformation behavior - of geomaterials, geosynthetics and of composite systems made of geomaterials and geosynthetics - with mechanically clean ren boundary conditions - can be determined. The examination is optionally carried out in the "Scherver such "and / or" undressing attempt ".

The testing device according to the invention ensures mechanically clean kinematic and kinetic edges conditions in the tested material or composite. The test device offers the special Advantages that the location of geosynthetic layers when examining geosynthetic Geomaterial composite systems through the consolidation process during test preparation is only slightly influenced, the negative effects of the wall friction on the experiment result can be eliminated, an exactly linear movement of the shear frame to each other in horizontal direction and a number, compared to today's geosynthetic Test practice, more innovative shear and pull-out test types are made possible.

The task is solved by a frame shear device with a specially designed frame. The test device according to the invention consists of a tilt-free, horizontally guided, ge mutually displaceable upper and lower load frame, which is via a hoist in the Adjusted the height and the horizontal translation by locking to the basic structure of the Tester can be prevented. The load frames each contain an upper and lower shear frame unit. These consist of a vertically movable - floating - Shear frames, each consisting of a load and a sample part, the one another and can be locked to the load frame. Each unit contains a decoupled one Load unit for applying the normal stress, a shear abutment, filter stones, the  are connected to the drainage opening on the device wall with drainage holes, as well as lateral normal tension abutments and stenter.

Other components of the test device include the water pan and a rigid base plate, a fixed, horizontally movable, drive-side clamping jaw on the built-in table for slipping secure connection of the tested geosynthetics. The clamping jaw on the drive side can Need to be connected to the drive rod, where normally a device for Pulling the top and / or bottom load frame is attached. The drive can be power or Feed controlled with constant or variable speed as well as pulling or pushing operate. For installing and compressing the geomaterial samples to be examined the sample parts of the shear frame are transported to a work table via a transport rail leads.

The test device according to the invention includes a force applied to the drive rod and a displacement transducer for measuring the resulting tangential force in the shear level and the driven shear path. Another four force transducers are on the carriage of the Linear bearing of the horizontal guide of the upper load frame, exactly in the shear plane, for Measurement of the resulting normal force attached to the shear plane.

Advantageous refinements are specified in the subclaims.

The test device according to the invention is characterized by ease of use, improved Power flow and strengthened consolidation methodology, especially when trying to pull out. A great advantage of the invention lies in the cheaper experimental logistics, since the operation of the Tester does not require the need for free lifting of large masses.

The testing device according to the invention enables shear and pull-out tests with easily reproducible boundary conditions with the following operating conditions:

• - Sample area: 500 mm × 500 mm
• - Variation of the vertical stresses in typical building areas (0 ... 600 kPa)
• - One-sided or two-sided application of the normal stress
• - Force or feed controlled with constant or variable speed as well as ze shear operated or pushing
• - Maximum pulling or pushing force in the direction of push: 125 kN  
• - Maximum travel in the direction of thrust: 200 mm
• - Horizontal floating and / or fixed shear boxes
• - Stepless shear gap: min. 0. , , 50 mm
• - Sampling of geomaterials and / or geosynthetics.

The invention is explained in more detail below using an exemplary embodiment. In the associated drawings show:

Fig. 1 cross section of the tester;

Fig. 2 longitudinal section of the testing device;

3A-3I types of experiment FIG..

As can be seen from FIGS. 1 and 2, the test device consists of a working chamber 34 which is delimited by a rigid base plate 32 and a water pan 33 . Outside the working chamber 34 is the drive 45 , which causes shearing or pulling out, in addition the device (not shown here) for generating the pressure in the upper loading unit 3 and the lower loading unit 4 , as well as the systems and computers for recording and evaluating measured values. Inside the working chamber 34 there is a built-in clamping jaw 40 attached to the basic structure 46 of the testing device, a working table 39 on which the sample part of the upper shear frame 7 b and the test part of the lower shear frame 8 b are prepared, who is connected to the drive 45 Drive rod 42 , to which a force transducer for measuring the resulting tangential force 43 in the shear plane 47 and a displacement transducer 44 for measuring the shear path are attached. Furthermore, depending on the test regime, a drive-side clamping jaw 41 or a device for pulling or pushing the upper load frame 1 and / or the lower load frame 2 is mounted on the end of the drive rod 42 . In the working chamber 34 there is a tilt-free, horizontally guided, ge mutually displaceable upper load frame 1 and lower load frame 2 , which is adjusted in height by means of a lifting mechanism 24 and the horizontal translation can be prevented by a locking mechanism to the framework 46 of the testing device. To detect the actual stresses in the shear plane 47 , four force transducers for measuring the resultant normal force 25 in the shear plane 47 are attached to the carriage of the linear bearing of the horizontal guide of the upper load frame 26 . In the upper load frame 1 is an upper shear frame unit and in the lower load frame 2 is a lower Scherrahmenein unit. The upper shear frame unit consists of a vertically movable - floating - upper shear frame 7 , which in turn consists of a loading part of the upper shear frame 7 a and a sample part of the upper shear frame 7 b. The upper shear frame unit also consists of an upper load unit 3 , an upper shear abutment 5 , upper filter stones 11 , which are connected to the upper drainage opening 12 on the wall of the device with drainage holes, as well as lateral normal voltage abutments of the upper shear frame 36 , carriage of the linear bearing of the vertical guide of the upper shear frame 19 , trolley of the upper shear frame 21 and an upper stenter 9 . The lower shear frame unit consists of a vertically movable - floating - lower shear frame 8 , which in turn consists of a loading part of the lower shear frame 8 a and a sample part of the lower shear frame 8 b. The lower shear frame unit also consists of egg ner lower load unit 4 , a lower shear abutment 6 , lower filter blocks 13 , which are connected to the lower drainage opening 14 on the wall of the device with drainage holes, and lateral normal stress abutments of the lower shear frame 38 , carriage of the linear bearing of the vertical guide of the lower shear frame 20 , trolley of the lower shear frame 23 and a lower stenter 10 .

The between the upper load frame 1 and lower load frame 2 during the experiment relative displacement is possible via the carriage of the linear bearing of the horizontal guide of the upper load frame 26 and the rail of the linear bearing of the horizontal guide of the upper load frame 27 , furthermore that between the basic structure 46 and lower load frame 2 relative displacement occurring during the experiment on the carriage of the linear bearing of the horizontal guide of the lower load frame 28 and the rail of the linear bearing of the horizontal guide of the lower load frame 29 possible, which can accommodate all force components, except in the direction of thrust. The assembly of the upper load frame 1 and lower load frame 2 and the upper shear frame unit accommodated in the upper load frame 1 and the lower shear frame unit accommodated in the lower load frame 2 is provided with a lifting mechanism 24 for lifting and lowering. By lifting of the composite, the moving out of the sample portion of the upper shear is frame 7 b and the sample part of the lower shear frame 8 b - separately or together - on attached to the upper shear frame 7 dolly upper shear frame 21 and at the lower shear frame 8 mounted dolly upper shear frame 23 as possible via the transport rail 22 on an installation table 39 , where installation and removal work are carried out. To transfer the built-in sample part of the upper shear frame 7 b or the built-in sample part of the lower shear frame 8 b in the upper load frame 1 or in the lower load frame 2 , an auxiliary plate is used. The height of the force input can be largely adjusted to the height of the shear plane 47 by lifting the bond between the upper load frame 1 and the lower load frame 2 without tilting moment.

To reduce the effects of friction between the upper sample body 15 and the Pro of the upper shear frame 7 b and the lower test specimen 16 and the sample portion of the lower shear frame 8 is benteil b the upper shear frame 7 as well as the lower shear frame 8 the possibility of vertical movement during the experiment given, with which the shear gap width can result from the experiment. For this purpose, the upper shear frame 7, further the lower shear frame 8 on the carriage of the linear bearing on the carriage of the linear bearing of the vertical guide of the upper shear frame 19 and the attached to the upper loading frame 1 rail of the linear bearing of the vertical guide of the upper loading frame 17 of the vertical guide of the lower shear frame 20 and on the lower load frame 2 attached rail of the linear bearing of the vertical guide of the lower load frame mens 18 out. By locking the upper shear frame 7 as well as the lower shear frame mens 8 with the device for locking the upper shear frame halves 35 and the on device for locking the lower shear frame halves 37 to each other, further to the upper loading frame 1 and the lower loading frame 2 with the grub screw to Arretie ren of the upper shear frame 30 and the grub screw for locking the lower shear frame mens 31 , the controlled setting and exact request of a shear gap width can take place during the entire test procedure. The dead weight of the upper shear frame 7 and lower shear frame 8 is compensated for by means of counterweights.

Homogeneous load conditions in the geosynthetic loose rock composite examined are created by using the upper load unit 3 and the lower load unit 4 . The upper load unit 3 is attached to the upper load frame 1 and the lower load unit 4 is attached to the lower load frame 2 . In this way, disruptive vertical displacement effects in the consolidation phase can largely be averted, which are particularly advantageous in the interaction attempt between geomaterials, geosynthetics and geomaterial, as well as during the pull-out attempt. By disassembling the lower load unit 4 , the load on the upper load unit 3 and voltage entry on the upper free surface of the upper test specimen 15 can be restored, which in the investigation of the friction between geomaterial in the sample part of the upper shear frame 7 b and a clamped on solid material Geosynthetics in the sample part of the lower shear frame 8 b is required. In order to prevent the constriction of the upper load unit 3 and the lower load unit 4 , the upper shear frame 7 is divided into a loading device part of the upper shear frame 7 a and a sample part of the upper shear frame 7 b and for testing with a device for locking the upper shear frame halves 35 attached to each other, correspondingly, the lower shear frame 8 is divided into a loading part of the lower shear frame 8 a and a sample part of the lower shear frame 8 b and fastened to each other for testing with a device for locking the lower shear frame halves 37 . The loading of the upper loading unit 3 and the lower loading unit 4 is realized with two pressure systems that are completely separate from one another. The shear stress entry in the upper specimen 15 and in the lower specimen 16 takes place via the upper shear abutment 5 and the lower shear abutment 6 on the upper free surface of the upper specimen 15 and on the lower free surface of the lower specimen 16 . Thus, a pure stress boundary condition is effectively supported both in the normal and in the tangential direction at the load entry points of the upper sample body 15 and the lower sample body 16 .

The upper shear frame 7 as well as the lower shear frame 8 is provided as required in the pushing direction with a lateral normal-voltage abutment of the upper shear frame 36 and with a lateral normal-voltage abutment of the lower shear frame 38 , which act as a normal voltage abutment at high shear paths, thus causing a shift in the direction of the train is possible without exposing the tested material. The lateral normal tension abutment of the upper shear frame 36 and the lateral normal tension abutment of the lower shear frame 38 can be assembled and disassembled, with the result that disruptive influences in experiments in which they are not required can be avoided. The use of the lateral normal-voltage abutment is illustrated in the test types.

To prevent constriction effects of the tested geosynthetics during shearing, who stretched them onto the upper stenter 9 and the lower stenter 10 . Depending on the type of experiment to be carried out, the upper clamping frame 9 is attached to the sample part of the upper shear frame 7 b and / or the lower clamping frame 10 to the sample part of the lower shear frame 8 b. Furthermore, the geosynthetic layers to be examined are connected to the built-in table-side jaw 40 and / or the drive-side jaw 41 in a slide test.

The upper shear frame 7 and the lower shear frame 8 can, if necessary, be completely flooded for both shear and pull-out tests. To ensure adequate drainage upwards and make the bottom of test series with partially or saturated sample material to be granted, the upper shear frame 7 are disposed b upper filter bricks 11 in the sample portion which is all in the upper drainage opening 12 at the walls of equipment with Dränagebohrungen the are, furthermore, in the sample part of the lower shear frame 8 b, lower filter stones 13 are arranged, which are connected to the lower drainage opening 14 on the device wall with drainage bores.

The shear or pull-out force is introduced via the drive rod 42 connected to the drive 45 . Shear is force or feed controlled at constant or variable speed. The direction of displacement is reversible for the investigation of the hysteretic shear behavior of geosynthetic loose rock composite systems.

The instrumentation of the test device according to the invention for extended measurement tasks is carried out with special measuring equipment. The electronic system of the Ver Suchseinrichtung provides an infrastructure for these metrological sensors. The Da data acquisition is processed with a separate measurement data collector and for monitoring, Calculation and evaluation fed into a computer.

As can be seen from FIGS . 3A to 3I, the test device according to the invention enables a large number of test types.

Fig. 3A illustrates the principle of the test type geomaterials-geomaterials-shear test. In this type of experiment, the examined geomaterial is sheared off by moving the upper load frame 1 and the lower load frame 2 to each other. Shear stresses are entered by pulling or pushing on the upper load frame 1 or lower load frame 2 . The non-moving load frame is locked during the test to the framework 46 of the tester. The normal stress is optionally entered into the upper specimen 15 via the upper loading unit 3 and / or into the lower specimen 16 via the lower loading unit 4 . The geomaterial sample examined is installed simultaneously on the installation table 39 in the sample part of the upper shear frame 7 b and sample part of the lower shear frame 8 b. An auxiliary plate is used to transfer the built-in sample part of the upper shear frame 7 b and the sample part of the lower shear frame 8 b into the upper load frame 1 and lower load frame 2 at the same time.

Fig. 3B illustrates the trial type geomaterials-geosynthetic-shear test. Here, the examined geomaterial in the upper load frame 1 is moved over the geosynthetic layer spanned in the lower load frame 2 on a solid base. Shear stresses are entered by pulling or pressing on the upper load frame 1 . The lower load frame 2 is locked during the experiment to the framework 46 of the tester. The normal stress is entered via the upper load unit 3 in the upper sample body 15 . The lower load unit 4 in the lower load frame 2 is removed for testing. The geomaterial sample examined is installed on the installation table 39 in the sample part of the upper shear frame 7 b. To transfer the built-in pro part of the upper shear frame 7 b in the upper load frame 1 , an auxiliary sheet is used. In the lower shear frame 8 , a low-deformation auxiliary construction (block) is inserted.

Fig. 3C illustrates the test type geomaterials-geosynthetic-geomaterials-shear test. In the experiment, a composite of geomaterial, geosynthetics and geomaterial is sheared off by shifting the upper loading frame 1 and the lower loading frame 2 relative to one another such that one or more geosynthetic layers are located exactly in the shear plane 47 . Shear stresses are entered by pulling or pushing on the upper load frame 1 or lower load frame 2 . The non-moving load frame is locked during the test to the framework 46 of the tester. The normal stress is optionally entered via the upper load unit 3 in the upper sample body 15 and / or via the lower load unit 4 in the lower sample body 16 . The geomaterial sample examined is installed separately on the installation table 39 in the sample part of the lower shear frame 8 b and then in the sample part of the upper shear frame 7 b. An auxiliary plate is used to transfer the built-in sample part of the lower shear frame 8 b into the lower load frame 2 as well as the sample part of the upper shear frame 7 b into the upper load frame 1 . The installation of the tested geosynthetic layer (s) is carried out between the installation of the sample part of the lower shear frame 8 b in the lower load frame 2 and the pro part of the upper shear frame 7 b in the upper load frame 1 . The tested geosynthetic layer (s) are firmly clamped in the lower clamping frame 10 or upper clamping frame 9 and fitted around the sample part of the lower shear frame 8 b or sample part of the upper shear frame 7 b and fastened thereon.

FIG. 3D illustrates the principle of the experiment type geomaterial-geosynthetics-geosynthetics-geomaterial interaction experiment. In this test variant, a composite of geomaterial and geosynthetics is sheared against a composite of geosynthetics and geomaterial by shifting the upper load frame 1 and the lower load frame 2 to one another in such a way that the geosynthetic layers are exactly in the shear plane 47 . Shear stresses are entered by pulling or pushing on the upper load frame 1 or lower load frame 2 . The non-moving load frame is locked during the test chu to the framework 46 of the tester. The normal stress is optionally entered via the upper loading unit 3 in the upper specimen 15 and / or via the lower loading unit 4 in the lower specimen 16 . The installation of the examined geomaterial sample is carried out on the built-in table 39 in the sample part of the lower shear frame 8 b and then separately in the sample part of the upper shear frame 7 b. To transfer a built sample part of the lower shear frame 8 b in the lower load frame 2 as well as the sample part of the upper shear frame 7 b in the upper load frame 1 , an auxiliary sheet is used. The installation of the tested geosynthetic layer (s) is carried out between the installation of the sample part of the lower shear frame 8 b in the lower load frame 2 and the sample part of the upper shear frame 7 b in the upper load frame 1 . The tested geosynthetic layer (s) are firmly clamped in the lower clamping frame 10 and upper clamping frame 9 and fitted around the sample part of the lower shear frame 8 b and sample part of the upper shear frame 7 b and attached thereto.

Fig. 3E characterizes the experimental type geomaterial-geosynthetic-geomaterial-coating experiment. In the experiment, a composite of geomaterial, geosynthetics and geomaterial is sheared off by pulling the upper load frame 1 over the geosynthetic layer stretched on the mounting-jaw jaw 40 such that one or more geosynthetic layers are exactly in the shear plane 47 and the lower load frame 2 is not hindered in its movement. Shear stresses are entered by pulling the upper load frame 1 . The normal stress is optionally entered into the upper specimen 15 via the upper loading unit 3 and / or into the lower specimen 16 via the lower loading unit 4 . The geomaterial sample examined is installed separately on the installation table 39 in the sample part of the lower shear frame 8 b and then in the sample part of the upper shear frame 7 b. To transfer the built-in sample part of the lower shear frame 8 b in the lower load frame 2 as well as the sample part of the upper shear frame 7 b in the upper load frame 1 , an auxiliary plate is used. The installation of the tested geosynthetic layer (s) is carried out between the installation of the sample part of the lower shear frame 8 b in the lower load frame 2 and the sample part of the upper shear frame 7 b in the upper load frame 1 . The tested geosynthetic layer (s) are fastened to the clamping jaw 40 on the built-in table, which is fixedly mounted.

Fig. 3F illustrates the experiment type geomaterial-geosynthetic-geomaterial-pull-out experiment. In this type of experiment, one or more geosynthetic layers are pulled out of a geomaterial composite in the upper loading frame 1 and the lower loading frame 2 in one direction such that the geosynthetic layer (s) are exactly in the shear plane 47 . Shear stresses are entered by pulling on the geotextile layer (s). The non-moving upper shear frame 7 and lower shearing frame 8 is during the test to each other and to the upper loading frame 1 further to the lower loading frame 2 arre advantage, in turn, the test instrument can be locked to the backbone 46th The normal stress is optionally entered into the upper specimen 15 via the upper loading unit 3 and / or into the lower specimen 16 via the lower loading unit 4 . The installation of the unexamined geomaterial sample takes place on the installation table 39 in the sample part of the lower shear frame 8 b and then separately in the sample part of the upper shear frame 7 b. To transfer the built-in sample part of the lower shear frame 8 b in the lower load frame 2 as well as the sample part of the upper shear frame 7 b in the upper load frame 1 , an auxiliary plate is used. The incorporation of the tested Geosynthetiklage (n) b between the installation of the sample part of the lower shear frame 8 in the lower loading frame 2 and the sample portion of the upper shear frame 7 b in the upper loading frame 1 easily taken. For the pull-out test, the tested geosynthetic layer (s) are fastened to the clamping jaw 41 on the drive side, which is movable.

Fig. 3G shows the type of experiment geomaterial-geosynthetic-geomaterial pull-through experiment. In the experiment, one or more geosynthetic layer (s) in a geomaterial composite in the upper load frame 1 and the lower load frame 2 are pulled in one direction such that the Geosynthetic layer (s) are exactly in the shear plane 47 . Shear stresses are entered by pulling on the geotextile layer (s). The non-moving upper shear frame 7 and lower shear frame 8 is locked to each other and optionally to the upper load frame 1 to the lower load frame 2 during the experiment, which in turn are locked to the framework 46 of the tester. The normal stress is optionally entered into the upper specimen 15 via the upper loading unit 3 and / or into the lower specimen 16 via the lower loading unit 4 . The installation of the geomaterial sample under investigation takes place on the built-in table 39 in the sample part of the lower shear frame 8 b and then separately in the sample part of the upper shear frame 7 b. To transfer the built-in sample part of the lower shear frame 8 b into the lower load frame 2 as well as the sample part of the upper shear frame 7 b into the upper load frame 1 , an auxiliary plate is used. The installation of the tested geosynthetic layer (s) is carried out between the installation of the sample part of the lower shear frame 8 b in the lower load frame 2 and the sample part of the upper shear frame 7 b in the upper load frame 1 . For the pull-through test, the tested geosynthetic layer (s) are attached to the fixed, built-in table-side jaw 40 and to the movable, drive-side jaw 41 .

Fig. 3H illustrates the trial type geomaterials-geosynthetic-geomaterials-overlap area pungsversuch. In the experiment, two or more geosynthetic layers are pulled in a geomaterial composite in the upper loading frame 1 and the lower loading frame 2 in one direction such that the geosynthetic layers are exactly in the shear plane 47 . Shear stresses are entered by pulling on the geotextile layer (s). The non-moving upper shear frame 7 and lower shear frame 8 are locked during the test to each other and to the upper load frame 1 to the lower load frame 2 , which in turn are locked to the basic structure 46 of the test device. The normal stress is optionally entered via the upper loading unit 3 in the upper specimen 15 and / or via the lower loading unit 4 in the lower specimen 16 . The installation of the examined geomate rialprobe takes place on the installation table 39 in the sample part of the lower shear frame 8 b and then separately in the sample part of the upper shear frame 7 b. To transfer a built sample part of the lower shear frame 8 b in the lower load frame 2 as well as the sample part of the upper shear frame 7 b in the upper load frame 1 , an auxiliary sheet is used. The installation of the tested geosynthetic layer (s) is carried out between the installation of the sample part of the lower shear frame 8 b in the lower load frame 2 and the sample part of the upper shear frame 7 b in the upper load frame 1 . For the overlap test, the tested geosynthetic layer (s) are fastened to the fixed, built-in clamping jaw 40 and to the movable, driving-side clamping jaw 41 .

Fig. 31 characterizes the geosynthetic constriction test type. For the constriction test, the tested geosynthetic layer is attached to the fixed, built-in table-side jaw 40 and to the movable, drive-side jaw 41 . Drafts in the geotextile layer are carried by pulling on the drive jaw 41 .

With a slight change in the experimental conditions, the invention can Other types of tests can be carried out.  

LIST OF REFERENCE NUMBERS

1

upper load frame

2

lower load frame

3

upper load unit

4

lower load unit

5

upper shear abutment

6

lower shear abutment

7

upper shear frame

7

a Load part of the upper shear frame

7

b Sample part of the upper shear frame

8th

lower shear frame

8th

a Load part of the lower shear frame

8th

b Sample part of the lower shear frame

9

upper stenter

10

lower stenter

11

upper filter stone

12

upper drainage opening

13

lower filter stone

14

lower drainage opening

15

upper specimen

16

lower specimen

17

Rail of the linear bearing of the vertical guide of the upper load frame

18

Rail of the linear bearing of the vertical guide of the lower load frame

19

Carriage of the linear bearing of the vertical guide of the upper shear frame

20

Carriage of the linear bearing of the vertical guide of the lower shear frame

21

Transport trolley of the upper shear frame

22

transport rail

23

Transport frame of the lower shear frame

24

hoist

25

Force transducers for measuring the resulting normal force

26

Carriage of the linear bearing of the horizontal guide of the upper load frame

27

Rail of the linear bearing of the horizontal guide of the upper load frame

28

Carriage of the linear bearing of the horizontal guide of the lower load frame

29

Rail of the linear bearing of the horizontal guide of the lower load frame

30

Grub screw for locking the upper shear frame

31

Grub screw for locking the lower shear frame

32

baseplate

33

water trough

34

working chamber

35

Device for locking the upper half of the shear frame

36

lateral normal tension abutment of the upper shear frame

37

Device for locking the lower half of the shear frame

38

lateral normal voltage abutment of the lower shear frame

39

worktable

40

built-in clamping jaw

41

drive-side clamping jaw

42

drive rod

43

Force transducer for measuring the resulting tangential force

44

transducer

45

drive

46

backbone

47

shear plane

Claims (5)

1.Testing device, in particular for testing the deformation behavior of geomaterials, geosynthetics and of composite systems made of geomaterials and geosynthetics, characterized in that the material or composite material to be tested in one, from a vertically freely movable upper shear frame ( 7 ) and a vertically freely movable lower shear frame ( 8 ) formed sample part of the upper shear frame ( 7 b) and sample part of the lower shear frame ( 8 b) is installed by an upper load unit ( 3 ) and a lower load unit ( 4 ) against a horizontally movable upper load frame ( 1 ) and the lower load frame ( 2 ) normal to the shear plane ( 47 ) and by horizontally shifting the upper shear frame ( 7 ) and the lower shear frame ( 8 ) to each other tangentially to the shear plane ( 47 ) so that the tested on the free outer edges Material in the horizontal direction purely kinematic and become purely kinetic boundary conditions in the vertical direction. 2. Test device according to claim 1, characterized in that the upper load frame ( 1 ) and the lower load frame ( 2 ) on the carriage of the linear bearing of the horizontal guide of the upper load frame ( 26 ) and the rail of the linear bearing of the horizontal guide of the upper load frame ( 27 ) are connected to one another and can be moved horizontally relative to one another. 3. Testing device according to claims 1 and 2, characterized in that the lower loading frame ( 2 ) on the carriage of the linear bearing of the horizontal guide of the lower loading frame ( 28 ) and the rail of the linear bearing of the horizontal guide of the lower loading frame ( 29 ) against the Basic structure ( 46 ) of the test device can be moved horizontally. 4. Testing device according to claims 1, 2 and 3, characterized in that the lower load frame ( 2 ) with a lifting mechanism ( 24 ) relative to the basic structure ( 46 ) is vertically movable. 5. Testing device according to claims 1, 2, 3 and 4, characterized in that the geosynthetics enclosed in the geomaterial-geosynthetic composite system with the aid of a fixed, built-in table-side jaw ( 40 ) and a movable, drive-side jaw ( 41 ) is held firmly and in tension can be charged.