The invention concerns a device for cutting and mixing soils that is adaptable to standard hydraulic excavators and that combines continuous cutting of sealing and stabilization trenches with admixture of stabilizing aggregates in a machinery unit.
For producing seals relative to dammed-up or flowing water in ground construction, such as embankments, dams, foundations, or river banks, ditch-like trenches are introduced. These trenches are subsequently filled with suspensions that are adjusted to be flowable and comprised of excavated soil, water, clay minerals, cement or lime. After curing of the suspension, the solidification, or physical separation of the water, a water-impermeable layer is formed.
A similar method is employed for stabilization of sections in the area of roads and rail tracks which sections are prone to settle or slide.
The introduction of trenches into the construction ground is done continuously or discontinuously.
In continuous methods, chain cutters are used wherein the components of the suspension are supplied to the trench and admixed during cutting. The main problem of this method is that the cutter chain has twice the length of the cutter boom and is therefore very heavy. Moreover, in case of a chain-shaped cutting tool approximately one half of the individual cutting tools are always in engagement which requires a power output design in accordance with maximum cutting depth. The total mass of a carrier machine with such a chain-shaped cutting device is at 3 m of trench depth almost 80 t and is therefore no longer suitable for soft soil, construction sites with minimal carrying capacity of the soil, or narrow roadside emergency lanes. Moreover, the machine is expensive and transport to and from the construction site is very complex with regard to logistics. This technology is therefore only suitable for large construction sites with appropriate soil conditions.
Such a trench cutter excavator with the aforementioned disadvantages is disclosed in the publication DE 198 58 151 A1.
In addition, the company ALLU Finland Ltd. offers a soil processing system for stabilizing soft soils, in particular clay, peat and slurry soils.
In this connection, a hydraulic mixing device as an excavator attachment is used that by means of two horizontally arranged drums mixes the soft soil with a supplied suspension or a binder. The drums that rotate in three planes ensure in this connection a controlled thorough mixing of the soil to be stabilized.
The excavator, as attachment carrier, moves in this connection horizontally at a right angle to the axis of rotation of the mixing drums. With this device working depths of five meters can be realized. The device is suitable however exclusively for stabilizing soft soils.
In discontinuous methods for introducing trenches first several bores that are adjoining each other are introduced with vertically operating mast-guided cutter heads. In this connection, the loosened soil is generally conveyed out of the trench area, a suspension is added and admixed, and then the mix is refilled into the produced trench as a plastic or flowable mass.
For this purpose, special excavator carriages are used that are redesigned as drilling machines with masts. In this connection, advancing requires a continuous repositioning of the excavator. A disadvantage is that the production of the trenches by introducing several adjoining boreholes and the introduction of the mixture of excavated soil and suspension that is adjusted to be flowable is temporally separated and is realized with different equipment. A further disadvantage resides in that the thus produced cut-off trenches are geometrically comprised of a number of overlapping or contacting boreholes so that upon refilling no uniform, and thus long-term stability, water-resistant sealing action can be ensured.
The object of the invention is to eliminate the known disadvantages of the prior art and to propose a simple and inexpensive device for cutting and mixing soils that is adaptable to standard hydraulic excavators and that enables continuous cutting of sealing and stabilization trenches as well as the simultaneous admixture of stabilizing aggregates.
According to the invention this is object is solved by the features of the independent claim. Preferred embodiments are disclosed in the dependent claims.
The device according to the invention for cutting and mixing soils for stabilization of soil materials in trench-shaped soil bodies is embodied as rotating and movable combination tool. The cutting and mixing unit is comprised of a cutting drum and a mixing drum which are supported on a common shaft in a shaft housing.
The cutting drum that is provided with teeth at the end face and circumference loosens the soil to be processed. By the arrangement of the cutting and breaking tools on the end face and the circumference of the cutting drum, the loosened soil is moved in the direction of the downstream mixing drum. The mixing drum has on the circumferential surface a number of spaced apart vanes that are arranged such that a stream is produced in axial direction opposite to the advancing direction and that process the loosened soil with the supplied aggregates and the mixing water to a flowably adjusted mixture that fills the produced trench.
The use of exchangeable hard metal-equipped cutting and breaking tools enables higher advancing speeds and a substantially continuous operation even for a limited amount of rubble and weathered rock.
Advantageously the cutting or breaking tools on the end face of the cutting drum are arranged close to the circumference. Advantageously, the cutting tools that are arranged on the circumference form a spiral line that conveys toward the shaft housing. Moreover, advantageously the commonly driven cutting and mixing drums are supported on a common shaft in the shaft housing.
In an alternative, also preferred, arrangement the cutting and mixing drums are separately driven so that as a function of the soil conditions the rotary speed or the circumferential speed and/or the torque of both drums can be controlled or regulated independently.
In an alternative, also preferred, arrangement the common d rive shaft for the cutting and mixing drums is driven by a conical gear set and a vertical shaft.
Moreover, the shaft housing is closed off by an upper connecting housing that receives the drive motor for the vertical shaft and the connecting surface for receiving the lifting mast or, in case of minimal working depth, is directly mounted by means of a connecting plate to the boom of the excavator.
In a further advantageous embodiment, the supply lines forwater and the aggregate are mounted on the shaft housing and open at the center axis of the cutting and mixing shaft such that aggregates are supplied directly at the mixing location.
It is moreover advantageous that the lifting mast, that has the device for cutting and mixing arranged at its bottom end by means of cables, is supported in a slidable way on a guide unit.
In a further preferred embodiment the guide unit is arranged on the boom of an excavator to be pivotable in a vertical plane that is positioned in the direction of the trench axis or on a support frame at the front end.
In another preferred embodiment the position of the exchangeable cutting and breaking tools on the end face and/or the circumferential surface of the cutting drum is adjustable. In another preferred embodiment, the position of the vanes and/or their engagement angle relative to the longitudinal axis of the mixing drum is adjustable. In this way, there is the possibility to adjust the device individually to a given soil condition.
One embodiment of the invention will be explained in the following with the aid of two Figures in more detail.
It is shown in:
The leading cutting drum 6, viewed in advancing direction, is provided at the end face with several easily exchangeable cutting tools 2 for end face cutting and has on its circumference a number of spirally arranged, displaced cutting tools 2. The common vertical drive shaft 13 is supported in the shaft housing 3 and drives a conical gear unit 14, not illustrated in detail.
On the other end of the drive shaft there is the mixing drum 4 having on its circumference a number of exchangeable mixing vanes 5 arranged in a coil shape such that the cut soil material is conveyed in the direction of the already produced trench and at the same time an intimate mixing with water and the stabilization medium is realized that is supplied through the medium lines 7 arranged on the shaft housing 3. The device is mounted on an excavator 11.
The formation of a flowably adjusted clay suspension is assisted as a result of the shearing forces acting within the mixing stream. Because of the advantageous superposition of the cutting movement, the advancing movement and the mixing drum 4 rotating within the same medium, a continuous and homogenous trench filling is realized, and its extension and dimensions are ensured necessarily.
The shaft housing 3 accommodates the hydraulic drive motor 12 supported at the upper end as well as the drive shafts 15 their bearings as well as the sealing elements for the cutting and mixing drums 1 and 4 and transmits at the same time through the housing wall the occurring forces and moments into the vertically movable lifting mast 6. On the lifting mast 6 and on the shaft housing 3 the supply lines 7 for suspension, water and/or lime cement powder are arranged.
The box-shaped lifting mast is supported in a guide unit 8. The vertical advancing movement of the cutting and mixing device is realized by hydraulic winches 9 mounted on the lifting mast 6.
The guide unit 8 is mounted on the basic boom or a special lateral support frame of an excavator 11 and is moved by means of the one tilting cylinder. The selection of the excavator depends with respect to power output on the soil type and with respect to weight on the length and weight of the lifting mast.
For use at the construction site the excavator is aligned with the mounted cutting and mixing device in the direction of the trench.
For starting work, a starter pit of the desired depth is required which enables lowering of the lifting mast 6 at an angle of approximately 60°-85°. The starter pit is filled with water and aggregate material and by movement of the lifting mast 6 with the cutting and mixing unit is processed to a liquid mass 12. The working advancement of the device is realized by boom adjustment and movement of the excavator.
With the cable 10 and the boom the lifting mast 6 is placed into the starter pit for starting the cutting action.
By superposition of the rotational movement of the cutting drum 1, that cuts with the end face and circumferentially, and the vertical advancing movement of the lifting mast 6, across the working depth a soil strip is processed at a width that corresponds to the diameter of the cutting drum 1. The horizontal advancement of the device is realized by continuous or stepwise movement of the excavator.
During cutting, water and stabilization medium (lime, cement, clay) are supplied immediately to the working area through the medium lines 7 which extend along the lifting mast 6 and in the shaft housing 3.
Number | Date | Country | Kind |
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10 2008 016 673 | Mar 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/053606 | 3/26/2009 | WO | 00 | 12/14/2010 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2009/118386 | 10/1/2009 | WO | A |
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Entry |
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Machine translation of EP 1273411 document Nov. 1, 2013. |
Number | Date | Country | |
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20110089745 A1 | Apr 2011 | US |