DE10048089C2 - Device for the monolithic removal of floor columns - Google Patents

Description

The invention relates to a device for monolithic Removal of floor columns, especially with large volumes, according to claim 1.

For investigations of the water and substance balance in soils in field lysimeters or column apparatus in the laboratory undisturbed floor columns are required.

Previous removal technologies have required the use of large ones Construction machinery or special devices such as excavators, Wheel loader, trestle with pulley and ballast, to do that Pushing or ramming the lysimeter vessel into the ground (DVWK Water Management Rules, Issue 114, 1980 "Recommendations for the construction and operation of lysimeters ", Pütz, Th., Stork, A., Führ, F .: Lysimeter-Accomprehensive Approach of Environmental Research, publication research center Jülich from April 8th, 1997; DIN 19672, sheet 1, 1968).

Pressing into the ground presupposes that Lysimeter tube is dug around. The vertical Alignment of the lysimeter vessel to the depth of the can are not guaranteed. Directional corrections that are usually carried out with the same excavator, usually lead to breakdowns in the monolith, causing the original floor structure with its trained Pore system destroyed and thus the accuracy of the water and material household investigations to be carried out be permanently impaired. On top of that, through digging up the lysimeter vessel without being there Pressing it into the ground is impossible, a bigger one Excavation pit in the extraction area arises, their manufacture  and securing is cost-intensive and also the location damaged.

A special device is known with which the Impact and often not continuously feasible pressing of the lysimeter vessel into the ground can be improved (Hantschel, R .: "New building one Lysimeter system at the GSF Research Center for Environment and Health ", communications from the German Soil Science Society, 1993, ISSN-0343-107X, volume 71, pp. 135-138).

With this device the force is applied over several continuously working spindles on the lysimeter tube transfer. A breakout of the vessel from the vertical is arranged by the around the lysimeter Spindles prevented. The one with this extraction technology necessary press-in forces are very high. It's the Use of extensive construction technology required, which also must have a high weight (approx. 50 to 100 t Net mass). Such techniques are costly and in many locations due to the limited accessibility Not insertable.

There are also a variety of methods and Devices for removing small-volume floor columns for soil, sediment and soil investigations as Known samples, which are then further investigated in the laboratory, destroyed and discarded or for later investigation be kept (DE 31 49 946 A1, US 43 163 93, US 13 013 95, GB 212 02 07 A, DE 42 17 695 A1, US 14 569 83).

The extraction is from US 14 569 83 and from DE 196 23 780 C2 known from laboratory columns or columns for batch tests. It this is a completely different scale range than in the production of large-volume floor columns for Lysimeter, i. H. around much smaller pillars (liners). at the columns are not lysimeters in shape of a measuring device, but only around objects for  Examination of certain parameters, not as with the Lysimeter for the study of complete processes or their simulation. A planting of these smaller ones Columns are not provided and also not possible.

In US 14 569 83 a device for Soil sampling from the undisturbed zone described, in which a core tube has an outer worm gear is introduced vertically into the ground, being at the top a pre-cutting device is arranged. There occur very high torques that are difficult to control, if a soil pillar with larger dimensions is removed shall be. The device is only for the removal of small-volume floor columns can be used economically. The The screw conveyor described is not for everyone Suitable for soil types and is quickly jammed by stones or glued through damp soil.

From DD 214 214 a method is known which the Possibility to constructively design a vacuum device treats to the base of the lysimeter to win the leaking water. It doesn't flow according to the principle of gravitation, but is by Vacuum applied.

The described large-volume soil sampling using a lysimeter has all the disadvantages of "Pricking cylinder principle" and requires the use heavy engineering, which disturbs the natural environment the soil sample.

In DE 39 01 077 C1 the disadvantages, which are the Pressing in the floor pillar arise through the intended The pages were only partially cut free.

The process sees the digging of a trench, the arrangement of cutting discs, the formation of the Lysi meter vessel as a polygon, the formation of a  Support structure and the pressing of the cylinder over an excavator bucket with the associated high Compressive forces to press in the cylinder and this existing risk of occurrence of a hydraulic Grundbruch, before.

The object of the invention is a Develop device with which the described Disadvantages of the prior art are avoided and with which is the monolithic removal of floor columns, especially with large volume, so it is guaranteed that the natural soil structure is largely preserved remains, so that water movement and mass transfer can be done in the same way as in the original natural, naturally grown soil structure at the site.

The object of the invention is achieved by the device solved the features of claim 1.

In this device, a support crossbar with an axial and radially adjustable guide for linear vertical Guidance of a lysimeter vessel receiving the soil column available until the intended extraction depth is reached, being on the floor facing side of the Lysimeter vessel a milling unit and a drive for radial pre-cutting of the contour of the floor column arranged are, the lysimeter vessel by its own weight in penetrates the floor, the milling unit a Has milling sleeve that the lysimeter vessel with radial play and encircling teeth has, in which the drive engages, which by means of another cuff firmly with the lysimeter tube is connected, on the milling collar at its the Floor facing side adjustable in its working angle Soil chisels with cutouts are arranged that the Grip the flange of the lysimeter tube.  

With this device in particular the removal large-volume floor columns, also of more than one meter Diameter and more than two meters in length, largely without disturbing the natural soil structure with one acceptable and strong compared to known methods guaranteed reduced effort and effort.

The removal of floor columns in difficult terrain such as In some cases, river lowlands is only through the Use of such a device has become possible.

Advantageous embodiments of the invention are in the Subclaims described.

Below, the device is based on a concrete Embodiment to monolithic Removal of a floor column of more than one meter Diameter and more than two meters in length explained.

In the accompanying drawing:

Fig. 1 is a schematic representation of the overall view of the device and

Fig. 2 is a schematic representation of the design of the milling device and teeth with the lysimeter vessel.

A lysimeter vessel 3 , which is to receive the soil column, is aligned exactly perpendicular to the soil surface by means of a support crossbar 1 and is fixed in this orientation by means of a lysimeter guide 2 until it is completely removed. On the bottom facing side of the lysimeter vessel 3 , a Fräsein unit 4 is arranged, which concentrically surrounds the lysimeter vessel 3 . The milling unit 4 pre-cuts the contour of the monolithic soil column to be extracted, so that the advancing lysimeter vessel 3 forms the final contour of the soil column. The bottom column completely fills the lysimeter vessel 3 when the removal depth is reached.

In Fig. 1, a removal device is shown, which consists of a three-legged support crossbar 1 with a suspended lysimeter guide 2 , which fixes the lysimeter vessel 3 in its position from the bottom surface to the intended removal depth. The lysimeter 3 is guided in a line at three points. At the lower end of the lysimeter vessel 3 there is a drive 8 and the milling unit 4 .

The drive 8 consists of a hydraulic motor and is firmly connected to the lysimeter vessel 3 by means of a sleeve 9 . The drive 8 can also be designed as an electric motor or pneumatically.

The milling unit 4 consists of a milling collar 5 which surrounds the lysimeter vessel 3 with radial play. The milling collar 5 can rotate freely around the lysimeter vessel 3 and has circumferential toothing 7 , in which the drive 8 engages.

Six pieces of ground chisel 6 are arranged at the end of the milling collar 5 facing the ground.

It can be seen from FIG. 2 that these chisels 6 have cutouts 13 with which they surround the flange 14 of the lysimeter vessel 3 . When turning the milling collar 5 , the chisels 6 cut into the ground and, with their milling 13, pull the lysimeter vessel 3 into the ground. The pre-cut soil monolith is cut into its end contour by means of a lysimeter knife 12 and is taken up over the entire surface by the lysimeter vessel 3 . A pushing device 10 ( FIG. 1), which consists of a hydraulic cylinder and an axial introduction of force 11 into the lysimeter vessel 3 , serves to support the driving force.

After the intended removal depth has been reached, the soil monolith (soil column) is separated from the grown soil in a suitable manner, lifted out of the removal location with the lysimeter vessel 3 , transported to the lysimeter station and set up for carrying out the experiment.

Claims (3)

1. Device for the monolithic removal of soil columns, in particular with a large volume, a support crossmember ( 1 ) with an axially and radially adjustable guide ( 2 ) for linear vertical guidance of a lysimeter vessel ( 3 ) receiving the soil column until the intended removal depth is reached is present, with on the bottom facing side of the lysimeter vessel ( 3 ) a milling unit ( 4 ) and a drive ( 8 ) for radially cutting the contour of the soil column are arranged, the lysimeter vessel ( 3 ) by its own weight in the soil penetrates, the milling unit ( 4 ) having a milling sleeve ( 5 ) which surrounds the lysimeter vessel ( 3 ) with radial play and has circumferential teeth ( 7 ) into which the drive ( 8 ) engages, which is actuated by means of a further sleeve ( 9 ) is fixedly connected to the lysimeter vessel ( 3 ), with the milling collar ( 5 ) on its side facing the bottom in it Rem working angle adjustable ground chisel ( 6 ) with cutouts ( 13 ) are arranged, which comprise the flange ( 14 ) of the lysimeter vessel ( 3 ). 2. Device according to claim 1, wherein the lysimeter vessel ( 3 ) for producing the end contour of the soil column has a circumferential cutting edge ( 12 ). 3. Device according to claim 1 or 2, wherein with the crossmember ( 1 ) a pushing device ( 10 ) is connected, which is connected via an axial force introduction ( 11 ) to the lysimeter vessel ( 3 ) and to support the dead weight of the lysimeter vessel ( 3 ) can be used.