DE19845132A1 - Compacting method for e.g. unconsolidated rocks uses one or more rotating spirals, with shape, length, pitch, direction, speed, all dependent upon edge conditions - Google Patents

Abstract

Compacting is achieved by rotating one or more spirals in the loose ground. Shape, length, pitch, direction of pitch left or right, direction of rotation, RPM, and torque, are variable dependent upon edge conditions. Gas, liquid, or a liquid-solid mixture, is ejected from the spiral via nozzles or openings, to accelerate, support, improve the lowering and compression process dependent upon requirements. To reduce wear, the spiral consists of a wear-proof material and/or has a wear-proof jacket.

Description

An important task in the solution of basic engineering and soil mechanics problems are the compression of cohesive and non-cohesive compaction material. Such problems are both artificial and natural Materials, e.g. B. Soils on dumps, heaps, embankments, dams, landfills and on To find building land for infrastructural facilities and waterways. An actual Examples of this are the compaction and securing of tipping and tipping risk Tipping embankments in the area of the former open-cast lignite mine in the new bun desländer.

In the past, one was used to solve the above-mentioned problems Numerous possibilities have been developed, the application of which depends primarily on the physi properties of the compacted material such as grain distribution, grain shape, storage density and water content as well as the geomechanical and hydrological boundary conditions conditions of the area - consisting of the compaction material and its surroundings - and depends on the compression target. In practice, the procedures are particularly explosive compression, vibrating pressure or vibrating plug compression and dynamic intensive comp seal applied.  

With an explosive compaction, an improvement of the soil mechanical properties the saturated loose rock by destroying the loose grain structure and achieved their rearrangement with simultaneous compression. The procedure is described in DD 286 724 A7, USA-22 36 759, DE 44 46 008 A1, DE 195 15 084 C1 in different Descriptions described.

Explosive compaction is only in spite of various advantages, especially due to high emissions limited possible. Explosive vibrations limit the use of this method Areas located some distance from housing developments, utility lines and other infrastructure. In addition, the process of stabilization Areas near the bank are only suitable to a limited extent because the risk of unwanted landslides is high is.

In the case of vibratory pressure compaction, the grain structure is created using a vibrator probe condensed. The lowering funnel resulting from the compression is made by earthworks filled devices. The scope of the procedure is limited to a very narrow range limited and particularly complex and expensive for larger densification areas intensive. This procedure is u. a. in DE 30 16 841 C2, DE 44 09 008 A1, DE 32 05 099 C2, DE 31 05 611 C2 and DE 29 48 403 described.

The process of vibrating pressure compression, which is associated with very high costs, takes place at for example, application where there is no blasting due to high blasting vibrations seal can be used. But even here, ecologically sensitive ab cuts are not stabilized without constant intervention. The accessibility of the site must be guaranteed. It is often only through costly embankments created by SKW. Sensitive, highly slippery sections cannot be edited since equipment and personnel are involved during compaction and backup are very close to the terrain to be compacted.

In materials in which grain rearrangement cannot be achieved by vibrations, is the improvement of the soil mechanical properties by shaking Foreign materials such. B. gravel column. This process is called vibratory plug compaction designated. The degree of soil improvement depends on the subsurface  mutual distance and the dimension of the compressed columns as well as the own remove the column material.

With dynamic intensive compaction, a weight is repeated by a certain one dropped to the area to be compressed. This procedure is u. a. out DE 23 51 713 C2 known. The horizontal and especially the vertical range of the Ver driving is limited so that powerful areas are not continuously compacted can. Because of the necessary high operating weight - equipment and drop weight - see above Like the type of initial effect, the process for compaction is certainly more sensitive Areas, e.g. B. near sections, unsuitable. In addition, the procedure is always with a complete destruction of the fauna and flora on the surface.

The object of the invention is to provide an effective and inexpensive method and a to create direction for the compression of binding and non-binding goods, which both on the degree of saturation or moisture of the compaction material as well as on the depth can be used dependent.

The object is achieved in that one or more wen in the compacted material rotated.

If a spiral with clockwise turns in a loose good in Rotation is offset, so this is drawn into the good, with the loose good upwards is transported. If the same spiral is in the good and this is contrary to the Turned clockwise, it transports the material that flows in or is fed down towards the helix tip. If the material is down is not subtracted, it is displaced or compressed. With increasing compression the helix moves out of the material as the rotation continues. The Regulation of compression can therefore be done via speed, torque and pressure force respectively. In addition to the displacement and the associated compression the compaction material in the direct sphere of action of a grain rearrangement, which also contributes to the compression. In addition, by rotating the Spiral cyclic impulses are introduced into the compaction material, which are also used for compaction to lead. These effects lead to an effective compression. A combination of several different helixes arranged with the same or different  Geometry, torque, speed, pressure, direction of rotation, screw direction and number of gears is possible.

The rotating spiral compaction and rotating spiral plug compaction are ideal conditions for the compaction of cohesive and non-cohesive goods. The advantages of these procedures are:

• - It can be used in security-sensitive areas.
• - It can be used regardless of the level.
• - A compression that is relatively independent of the load is achieved.
• - There are the three positive effects of material displacement, material circulation and Impulse introduction combined for compression.
• - The methods can be independent of the humidity or the degree of saturation of the Materials are used.
• - By changing the direction of rotation, the same device can penetrate serve to the desired depth and then work as a compacting device.
• - When using the process as a spiral compression, the desired Final depth quickly reached.
• - Liquids, liquid-solid mixtures or gases can be used to support the Penetration and / or compression process inside the boom and Wen del be transported. They then exit through openings or nozzles.
• - With the same device is both rotary compression and rotary plug compression possible.
• - The application of the method is in combination with a carrier device with boom possible for inaccessible or security sensitive areas.
• - The method can be used in the vertical direction as well as diagonally or diagonally perform sealing work.

Embodiments

Exemplary embodiments are shown in the drawings and are described in more detail below described:

Fig. 1 execution of the spiral compression in combination with a carrier device with boom

Fig. 2 Execution of the spiral twist plug compression in combination with a carrier device with boom

Fig. 3 Execution of the twist spiral or twist spiral plug compression in combination with a carrier device without boom, z. B. drilling rig (vertical operation)

Fig. 4 Execution of the twist spiral or twist spiral plug compression with a carrier device without a boom (inclined or diagonal mode of operation)

Fig. 5 execution of the twist spiral or twist spiral plug compression by the combination of two devices.

In the embodiment according to FIG. 1, the procedure for rotary spiral compression in combination with a carrier device which has a boom is shown in the partial illustrations AC. The carrier device ( 1 ) is connected by a connection ( 2 ) with the compression device consisting of the strand ( 3 ), the drive ( 4 ) and the Wen del ( 5 ). The strand and the coil are formed in the interior so that the substances required for process acceleration or improvement, such as gas, liquid or liquid-solid mixture, can escape through the openings or nozzles ( 8 ) located on the coil ( 5 ) . The drive ( 4 ) enables the speed, torque and direction of rotation to be changed. Depending on the task, the helix ( 5 ) has a different length, pitch, screw direction, shape, pitch and diameter. The strand ( 3 ) has different lengths and weights depending on the task.

In the first step, the compression device is selected by the direction of rotation depending on the screw direction similar to a screw in the compaction material sunk. After the desired depth is reached, the direction of rotation is reversed  and thus the compression process is initiated. Is the compression in the processed Zone reached, the device is withdrawn to the extent that by the following Compression creates a coherent compacted column. This approach is repeated until the entire thickness of the compaction material has been processed is. The compaction leads to a lowering of the surface, which is filled with material that can, a compression of this section also possible after backfilling is.

In the embodiment according to FIG. 2, the procedure for rotary spiral plug compression in combination with a carrier device which has a boom is shown in the partial illustrations AC. The device and its properties are the same as the device according to FIG. 1.

In the first step, a cavity is formed in the continuum, the mechanical property of which is to be improved as a result of the plugging. B. he makes a hole. This task can also be carried out with the compression device, in which case a auger is used as the helix ( 5 ). After the cavity has been completed, it is filled with compaction material. The filling quantity is variable and depends on the boundary conditions. The compaction device is now sunk in the compaction material. The compression process is initiated by selecting the direction of rotation of the helix ( 5 ) depending on its screw direction (right-handed or left-handed). Once compaction has been achieved, the device is pulled up and compaction material is added to the cavity again. The compaction device is lowered and the compaction process is initiated. The procedure described is repeated until the compacted column reaches the desired height.

In the embodiment of FIG. 3, the possibility of the application process of Figure 1. And Fig. 2 for example in combination with a carrier device without boom. B. drill Darge provides. The process steps remain the same as for Fig. 1 and described in FIG. 2.

In the embodiment of FIG. 4, the possibility of applying the Drehspiralverdich tung is shown the turning scroll compression pot, wherein a diagonal operation in combination with such a support device without boom. B. drill. The inclination of the inclined holes depends on the boundary conditions, especially on the material properties.

Rotary spiral and rotary spiral plug compression can also be used in that several compression devices are connected to one carrier device. This procedure leads to an increase in the compression performance and serves to compensate for reaction moments which arise as a result of the rotary movement of the helix ( 5 ) or the device. In the embodiment according to FIG. 5, the procedure is exemplarily shown for the combination of two compression devices.

The compression devices are interconnected via a cross-connection ( 9 ), the connection being designed such that a change in the distance between the devices is ensured. The cross-connection ( 9 ) is connected to the carrier device via a connection ( 2 ).

Claims (12)

1. The method and system for the compression of cohesive and non-cohesive material (e.g. loose rock) by means of rotary spiral compression or rotary spiral plug compression as characterized in that the compression is achieved by rotating one or more helixes in the loose material, the shape, the length , the pitch, the screw direction (right or left), the direction of rotation, the speed, the torque are variable depending on the boundary conditions. 2. The method according to claim 1, characterized in that to support Acceleration and improvement of the lowering and compression process each depending on the area of responsibility gas, liquid or liquid-solid mixture Openings or nozzles emerge from the coil. 3. The method according to any one of the above claims, characterized in that the helix for wear reduction is made of a wear-resistant material and / or is lined with a wear-resistant jacket. 4. The method according to any one of the claims listed above, that the drive integrated in any length along the compression device being the change in speed, direction of rotation and torque enables. 5. The method according to any one of the claims listed above, that as a carrier device both devices with cantilevers and devices without cantilevers Application come. 6. The method according to any one of the claims listed above, that several compression devices are arranged on a carrier device, where by choosing the technical data of the devices such as speed, Torque, direction of rotation and screw direction of the spiral one The reaction moments are compensated.   7. The method according to any one of the claims listed above, that about the regulation of the strand weight and / or the power consumption regulation of the degree of compaction takes place. 8. The method according to any one of the claims listed above, that the operation is carried out both vertically and diagonally or obliquely. 9. The method according to any one of the claims listed above, that the compression takes place both from the mainland and from the water. 10. The method according to any one of the claims listed above, that different thicknesses of the compacted material regardless of Moisture content can be processed. 11. The method according to any one of the claims listed above, that both for deep compaction and for compaction close to the surface Area is used. 12. The method according to any one of the claims listed above, that the compression starts from the desired final depth towards the upper surface is carried out or starting from the surface towards the final depth becomes.