EP3702534A1 - Testing device for bar anchors, in particular on loose soil - Google Patents

Abstract

A test device (1) for rod anchors (2), in particular in loose soil (LB), with a rod anchor extension (3) which is temporarily connected to the rod anchor (2); with an impact weight (4), which is movably guided on the rod anchor extension (3), and with an acceleration device (5) for accelerating the impact weight (4) in direction (R) onto a stop (6) attached to the rod anchor extension (3) .

Description

The invention relates to a test device for rod anchors and strand anchors, which are installed in particular on loose soil, according to claim 1.

Rockfall and avalanche protection barriers are mainly built in alpine areas. The erection, foundation, maintenance and testing of these structures is therefore complex and demanding. It has also been shown that especially the dynamic loading of these structures and, subsequently, the dynamic loading of the foundations, especially on loose soil, cannot be tested satisfactorily with static anchor tests.

If rockfall and avalanche protection barriers are built over anchored structures, especially on loose ground, this results in major problems of a technical and economic nature or blurring, especially in the anchor test, which is carried out statically with a hydraulic press in systems known from the prior art in evaluating and interpreting this test. For the production of the static anchor tests, extensive and time-consuming preparatory work must be carried out before the test. Since the test forces to be applied must be supported on the surrounding soil, steel girders or the like or specially manufactured auxiliary foundations are required.

When the test is actually carried out, static forces are applied to the test anchor in increasing load levels and the measurement results are documented. Since the resulting deformation is recorded with the load using a dial indicator, it must be ensured that the dial indicator (i.e. the tripod) is placed on neutral ground so that the settling that occurs does not cause errors in the measurement.

It's from the JP 2004-317 364 A a quick load test for a built-in pile is known, but this device would not be suitable for a rod anchor test, since in this known arrangement only a weight is provided that hits a stop of a guide rod by gravity and exerts a blow on the head of the pile via a complex load transfer device .

It is therefore the object of the present invention to create a test device for installed rod anchors which enables dynamic testing regardless of the strength of the subsoil, and which is preferably less complex, both technically and economically, than known test devices.

This problem is solved by the features of claim 1.

The test device according to the invention for rod anchors and strand anchors is in principle suitable for any arrangement of the rod anchors on a particular subsoil, but is particularly suitable for a rod anchor arrangement in soft ground (loose soil) and has a rod anchor extension for this, which can be a metallic extension rod, for example, whereby this rod anchor extension is temporarily connected to the rod anchor while the rod anchor is being tested.

Furthermore, the testing device according to the invention has an impact weight, which can also be referred to as an impact weight or shock weight. This impact weight is movably guided on the rod anchor extension for the purpose of performing the test.

Finally, the test device according to the invention has an acceleration device with which it is possible to accelerate the impact weight in the direction of a stop which is attached to the rod anchor extension.

With this test device, it is possible to carry out a test method that is independent of the soft subsoil (loose soil) or does not require the associated expenses, such as in particular heavy supporting structures or foundations. In addition, it is possible with the test device according to the invention to implement dynamic force application in the course of the anchor test in order to also be able to take into account the predominantly dynamic loading of these structures in practical use.

• Es ist möglich, dynamisch wirkende Lasten auf den Prüfanker aufzubringen, was auch der späteren Lasteinwirkung im Gebrauchszustand der Bauwerke entspricht.
• Es ist keine Abstützung auf den umgebenden Untergrund erforderlich. Die Abstützung bzw. Ableitung der Prüffolge erfolgt sozusagen auf sich selbst gestützt. Dies hat u.a. zudem den Vorteil, dass auch schief auf das Urgelände gebohrte Anker (z.B. seitliche Abspannanker bei Steinschlagschutzverbauungen) sowie generell alle Bauwerksanker mit der erfindungsgemäßen Prüfvorrichtung geprüft werden können.
• Durch die Ausbildung der erfindungsgemäßen Prüfvorrichtung ist es ferner möglich, dass die Prüfung in einem signifikant kürzeren Zeitraum und somit technisch einfacher und wirtschaftlicher möglich ist.

Overall, the test device according to the invention has the following advantages over devices known from the prior art:

• It is possible to apply dynamically acting loads to the test anchor, which also corresponds to the later load effect when the structures are in use.
• No support on the surrounding subsurface is required. The support or derivation of the test sequence is based on itself, so to speak. This also has the advantage, among other things, that anchors drilled at an angle to the primeval terrain (eg lateral tensioning anchors in rockfall protection structures) and generally all structural anchors can be tested with the test device according to the invention.
• The design of the test device according to the invention also makes it possible for the test to be carried out in a significantly shorter period of time and thus technically simpler and more economically.

Finally, the test device according to the invention has the advantage that, in contrast to the test devices known from the prior art, the required Energy to generate the test forces does not have to be generated hydraulically, but that due to the structure of the test device according to the invention, in particular pneumatic, mechanical (e.g. with steel springs) or chemical acceleration devices, such as propellant charges based on combustion, can be used.

To install the test device according to the invention, a rod extension is temporarily fixed on an anchor head of the rod anchor protruding from the subsoil, that is, for the purpose of carrying out the test. For example, an extension of about 1.5 m can be achieved here. However, this is only to be understood as an example, since the dimensions of the rod anchor extension depend on the respective installation conditions and other influencing factors and can be adapted accordingly.

The impact weight, which is movably guided on the rod anchor extension, can be accelerated by means of the acceleration device in the direction of a stop attached to the rod anchor extension, which, when the impact weight hits the stop, leads to forces acting on the rod anchor, which can be recorded and evaluated, in particular a dynamic one To determine the deformation modulus of the anchor system, the interpretation of which enables conclusions to be drawn about the quality or load-bearing capacity of the anchorage in the subsoil.

The subclaims contain advantageous developments of the invention.

A sleeve can be provided as an attachment option for the rod anchor extension on the rod anchor, which in principle can be connected to the anchor head and the rod anchor extension using any suitable fastening device, such as screw connections, clamp connections, adhesive connections, welded connections or the like, in order to achieve the desired temporary connection of the rod anchor extension to accomplish at the rod anchor. In order to even out the movement of the impact weight, it is preferably possible to arrange a sliding tube on the rod anchor extension on which the impact weight can be moved or accelerated with the least possible frictional resistance.

The stop to which the impact weight is accelerated can, for example, be a nut screwed onto the rod anchor extension, but it is also possible here to provide other types of fastening for the stop, such as a welded connection or a clamp connection.

The arrangement of the impact weight, the sliding tube and the stop can be arranged in a cladding tube in a further particularly preferred embodiment in particular to prevent contamination of the components arranged in the cladding tube, which could negatively affect the measurement. In this case it would be possible to design and use an end wall arranged opposite the impact weight as a stop.

In order to be able to further improve the evaluation of the test of the rod anchor, it is possible to arrange one or more acceleration sensors on the sleeve and, in a further particularly preferred embodiment, one or more strain gauges additionally or alternatively. If one or more acceleration sensors are provided, it is possible to evaluate the test by deriving the acceleration that occurs twice to make a statement about the movement or the deformation of the rod anchor.

A particularly simple embodiment for the acceleration device is a compressed air cylinder, since it is easy to transport and assemble and can be connected in a simple manner, for example to the jacket tube, via an in particular flexible connection hose, in order to feed compressed air into the jacket tube for the purpose initiate the acceleration of the impact weight. Alternatively, a chemical acceleration device, for example based on combustion, is also conceivable in order to be able to apply the required acceleration forces.

The invention also relates to a method for dynamic anchor testing of rod anchors, especially in loose soil, which comprises the following method steps:
In a first process step, the rod anchor is extended by a test section, the length and arrangement of which can be adapted to the respective assembly of the rod anchor and its structure.

After the test section has been arranged, an impact weight is attached to it and a stop is attached to one of the ends of the test section.

To carry out the test, the impact weight is accelerated in the direction of the stop to apply dynamically acting loads on the test section and after the impact weight has hit the stop, the loads acting on the rod anchor when the impact weight hits are determined in order to determine the effects of these dynamic loads, which correspond to the loads that also occur during operation of the rod anchor or the structure in which the rod anchor is integrated.

Further details, advantages and features of the present invention emerge from the following description of exemplary embodiments with reference to the drawing. The only The figure of the drawing shows a schematically greatly simplified representation of a test device according to the invention.

The test device 1 shown in the figure serves to check the arrangement of a rod anchor 2 in a subsoil, in particular in the form of loose soil LB. The rod anchor 2 has an anchor head 7 which protrudes from the subsoil, in particular the loose soil LB, so that in the particularly preferred embodiment shown in the figure it is possible to temporarily attach a rod extension 3 to the anchor head 7 via a sleeve 8. In this context, the definition "temporary" means that the rod extension is only connected to the anchor head 7 of the rod anchor 2 while the test is being carried out and the test device 1 can be separated again from the anchor head 7 and thus from the rod anchor 2 after the test has been carried out.

In addition to the rod anchor extension 3, which can be designed as a metal rod, which can correspond to the rod anchor in terms of its dimensions and choice of material, the test device 1 has a so-called impact weight 4 that is movably guided on the rod anchor extension 3.

As a further basic component, the test device 1 has an acceleration device 15 with which it is possible to accelerate the impact weight 4 in the direction R onto a stop 6 fastened on the rod anchor extension 3.

In the embodiment shown in the figure, the impact weight 4 is arranged on a sliding tube 9, which in turn is arranged on the rod anchor extension 3. This results in the advantage that the material and the surface properties of the sliding tube 9 can be designed in such a way that the lowest possible frictional forces occur when the impact weight 4 is accelerated, which preferably reduces or even eliminates falsifications of the measurements.

It is possible, as shown in the figure, to design the stop 6 as a nut screwed onto the free end of the rod anchor extension 3, but this is only one option. Of course, it would also be possible to weld the stop 6 onto the corresponding end of the rod anchor extension 3 or to fasten it in some other way, with only having to ensure that the stop 6 can withstand the impact of the impact weight 4.

In order to improve the test behavior of the test device 1 according to the invention, a casing tube 10 is preferably provided in the embodiment shown in the figure, in which the impact weight, the sliding tube and the stop 6 as well as the rod extension 3 are arranged. Such a cladding tube 10 has the advantage above all that contamination of the aforementioned components which are arranged within the cladding tube 10 can be avoided, which is particularly advantageous in that such contamination could falsify the test result.

In the particularly preferred embodiment shown in the figure, a threaded nut 12 is also screwed onto an end region 11 arranged outside the cladding tube 10 and a threaded nut 16 is screwed onto an opposite end section 11B adjacent to the sleeve 8, each of which protrudes from the cladding tube 10. If such a threaded nut 12 or a stop otherwise attached to the end area 11A of the rod extension 3 is provided, the stop 6 could also be omitted, since in this case the impact weight 4 could also develop its effect if it is shaped onto the end area adjacent to the nut 12 an end wall 17 of the cladding tube 10 would impinge.

In order to be able to evaluate the effects of the impact of the impact weight 4 on the stop 6, in the embodiment shown in the figure it is preferably provided to have at least one, preferably a plurality, of acceleration sensors 13 and at least one, preferably a plurality of strain gauges 14 to arrange the sleeve 8 in order to be able to determine according to the deformations occurring via appropriate evaluation methods, how the quality of the fixation or load-bearing capacity of the rod anchor 2 in the subsoil, in particular loose soil LB, is to be assessed.

In addition to the above written description of the invention, reference is hereby made explicitly to the graphic representation of the invention in the single figure of the drawing for the purpose of its supplementary disclosure.

List of reference symbols

1

Testing device

2

Rod anchor

3

Rod anchor extension

4th

Impact weight

4A, 4B

Impact weight bevels 4

5

Accelerator

5A

Valve / shut-off device

5B

Connecting device between the acceleration device 5 and an entry into a cladding tube 10

6th

attack

6A, 6B

Bevels of the stop 6, the bevel angle of which corresponds to the bevel angle of the bevels 4A, 4B

7th

Anchor head

8th

sleeve

9

Sliding tube

10

Cladding tube

11A, 11B

End areas

12

Fastening device / nut

13

Accelerometer

14th

Strain gauges

15th

Compressed air cylinder

16

Fastening device / nut

17th

Front wall

R.

Direction of acceleration

LB

Loose soil

Claims (11)

Test device (1) for rod anchors (2), especially in loose soil (LB), - With a rod anchor extension (3) which is temporarily connected to the rod anchor (2); - With an impact weight (4) which is movably guided on the rod anchor extension (3), and - With an acceleration device (5) for accelerating the impact weight (4) in direction (R) onto a stop (6) fastened to a free end of the rod anchor extension (3). Test device according to Claim 1, characterized in that the rod anchor extension (3) is connected to the rod anchor (2) via a sleeve (8) temporarily attached to an anchor head (7) of the rod anchor (2). Test device according to Claim 1 or 2, characterized in that the impact weight (4) is arranged on a sliding tube (9) which is arranged on the rod anchor extension (3). Test device according to one of Claims 1 to 3, characterized in that the stop (6) is designed as a nut screwed onto the rod anchor extension (3). Test device according to Claim 3 or 4, characterized in that the impact weight (4), the sliding tube (9) and the stop (6) are arranged in a casing tube (10). Test device according to Claim 5, characterized in that an end region (11A) of the rod anchor extension (3) is braced on the casing tube (10) by means of a threaded nut (12). Test device according to one of Claims 2 to 6, characterized in that the sleeve (8) has an acceleration sensor (13). Test device according to one of Claims 2 to 7, characterized in that the sleeve (8) has a strain gauge (14). Test device according to one of Claims 1 to 8, characterized in that the acceleration device (5) is designed as a compressed air cylinder (15). Test device according to one of Claims 5 to 9, characterized in that a fastening device (16), in particular in the form of a threaded nut, is arranged adjacent to the sleeve (8) on the rod anchor extension (3) and rests on the casing tube (10). Procedure for dynamic anchor testing of rod anchors (2), especially in loose soil (LB), with the following process steps: - Extension of the rod anchor (2) by a test section; - Arranging an impact weight (4) on the test track; - Arrangement of a stop (6) at a free end of the test section; - Accelerating the impact weight (4) in direction (R) onto the stop (6) to apply dynamically acting loads to the test track; and - Determine the loads acting on the rod anchor (2) when the impact weight (4) hits the stop (6).

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