DE4207420A1 - METHOD AND DEVICE FOR PROVIDING PALES IN THE GROUND - Google Patents

Abstract

System and machine for creating columns for consolidating in ground by virtue of forced injection of inert elements, which may be of granular nature, mainly sand or fine gravel, and consolidation agents and fluids, by virtue of tubes placed inside a penetration spindle, the lower end of which is used to grind up and loosen the ground, thus preparing it for the formation of the column of dry consolidated ground which is formed as the spindle is withdrawn. <IMAGE>

Description

The present invention relates to a receiving system of solidified columns made of soil material as well as on the Aus armor that makes up such a system.

In the area of consolidation and deep stabilization of unst organic soil materials (e.g. silt, silt, sand, clay, peat, Lignite (brown coal), etc.) is the technique of adding chemical agents such as calcium and cement to the Soil material known to improve mechanical egg properties of the soil material itself.

Such techniques were known to the Romans and Chinese who Silt (or fine deposits) with lime mixtures stabili based and solidified. There are currently many studies and Applications of these systems in Holland, France, Japan and Italy.

The technology currently used sees the formation of deep solidified piles or columns before using the following Pha sen:

• 1 - Mechanical breakup of the soil material by insertion a shredder / mixer with rotating cutting edge or display fel in the soil material, and dry for not together holding, loose soil material and with the help of water to the Penetration tool penetration into soft, coherent Bo to facilitate the materials.

In some applications, this disruption is achieved below Use of water by injecting fluid (water) with very high speed and pressure.

• 2 - Immission of stabilizing chemical agents into the Bo the material and its mixing with the soil material.

The applications used were different Technologies implemented, such as:

• a) forcing the dry chemical agent during pulling out the shredding mix tool, the Direction of rotation is reversed (Swedish L-C-M method), see: ATTI dell′ISTITUTO DI SCIENZA DELLE COSTRUZIONE - Politec nico di Torino, engineer Marco Bertero, Paolo Marcellino "DEEP STA- BILISATION "November 1981, No. 5, page 20.
• b) introducing the dry chemical agent through a lei device provided at the lower end of a screw conveyor and is at the top end of the shredding mix tool for feeding and distributing the agent in the soil material, and by simultaneously pulling out the tool Reversal of the direction of rotation (Japanese D-L-M method); (above publication) page 21.
• c) Introducing the chemical agent in a liquid state (Water-cement mixture) via a pipe, the lower end at the upper end of the comminution mix tool ter using a similar procedure as in the previous system of point b) (Japanese C-M-C method) (above mentioned publication) page 22.
• d) introducing the chemical agent in a flowing state (Water-cement mixture) via a line which runs axially to the Crushing Mix Tool is inserted and the outlet arranged according to the cutting edge or shovel of the same net, using a similar procedure as in the Systems described in points b) and c) above (Japanese D.M.C. process) (above publication) Page 23.
• e) Introducing the chemical agent in a flowing state (Water-cement mixture) over a hollow shaft that at the bottom of the shredding mix tool is attached. The introduction the mixing happens during the insertion and on phase  penetration of the tool into the soil material or terrain, and by means of pressure injection via side and bottom openings, which are arranged according to the tool. The tool is then pulled out when the direction of rotation is reversed (Italian procedure - ELSE) (above publication page 23).

The above mixing techniques, i. H. the introduction to that Soil material using dry systems with (lime-ze ment) powder materials or dampening systems with cement flow, ha ben the disadvantage that where the soil material has a structure, a substantial proportion of organic elements or a Excess sulfates are missing, or wherever there is a be shows a degree of porosity, the process of hydra tion of the binding material can be significantly delayed or becomes completely ineffective.

To overcome this disadvantage, it has been proposed that Zu sets, such as monogranular silicon sands, calcium or chlorinated carbonates or others, either granular or filiform, but not powdered, can be used to ensure the effectiveness of the treatment of the soil material len. The advantages of the present invention come from the one manufacture of the additives mentioned above, by means of forced immission of granular (granular) or filiform materials to create an inert structure in the treated Bo to form the material to improve mechanical properties to obtain.

The invention is described in more detail below ben with the help of the accompanying drawings, which is an off show leadership example. The drawing shows:

Figure 1 schematically shows the entire work unit for solidifying soil material in general.

Figure 2 is a partial section of the ground penetration bar.

Fig. 3 is a section along the line AA;

Fig. 4 shows one end of the floor material penetration rod during removal thereof;

Figure 5 is an axiometric view of Figure 4;

Fig. 6, the successive operating phases;

Fig. 7 shows schematically the function of propulsion (the propulsors);

Fig. 8 shows a detail of the propulsion (the propulsors) with the alternating game of the valves.

In Fig. 1, 1 denotes the mechanical arm for the rotation and penetration of the rod 2 for breaking and crumbling the soil material. The mechanical process of breaking and crumbling the soil material is accomplished by inserting a tool 3 , which is fixedly attached to the lower end of the penetration bar 2 , into the soil material. This tool 3 has two or more cutting edges (cutting blades) 4 . The tool is inserted into the soil material by a clockwise rotating thrust, either dry or with a circuit of fluids supplied through the tube 5 with the pump 6 which conveys the fluid from the container ter 7 . The fluids (liquids) are only supplied if the type of soil material requires this.

The dimensions of the cutting edge of the tool 3 determine the diameter of the pillar to be formed (pile) and the shape and inclination that are suitable both for insertion into the terrain (soil material) with the appropriate speed of advance as well as for breaking up and mixing the Soil material. The hollow rod 2 can be polygonal or cylindrical in section and is equipped on the inside with tubular lines, the central line 8 for guiding the solidifying materials and the adjacent line 9 for guiding the liquids for moistening the soil material surrounding the penetration bar. The fluids emerge from the tube 9 at points 10 , 11 in ra dialer manner. When the soil material has been broken up mechanically by means of the rod 2 with forced immission of sand or gravel, the rod begins to return to the surface and during this counterclockwise movement the forced immission of cement through the pipe 12 acts, which acts on Point 13 is connected to the central tube 8 of the hollow rod 2 .

The immission system equipment has the following: a feed device 14 , silos with cement and inert material 15 , an air bell 16 , a dryer 17 , a cooling unit 18 , a compressor 19 , which is necessary for the thrust of the propulsors 23 of the materials, and one Generator 20 . The solidifying mate rialien emerge from one or more connection openings 21 .

Depending on the stratification (stratification) of the soil material, the operator feeds fluid via line 9 for the necessary moistening of the soil material and the solidifying materials.

The solidification materials and possibly the fluids are forcibly fed into the soil material via the openings which are arranged such that the materials are distributed ra uniformly and uniformly so that the soil material is compacted and homogeneously solidified. This solidification is considered to be complete when the penetration rod is pulled out of the soil material, thereby forming a column of solidified soil material 22 . The system for solidifying soil material is based on the immission of sand or gravel in the penetration phase clockwise and on the immission of cement in the extraction phase of the penetration rod counterclockwise. The entire propulsion system therefore consists of two silos, one for sand or gravel and the other for cement. The material is alternately gelie manufactured by the silos 24-25 , in the chamber 26 to the inlet of the screw conveyor 27 , where a feed device 28 transmits the amounts of cement and sand or gravel, which supplies ge to the propulsors 29-30 will. These propulsors have an upper valve 31 that opens downward under the weight of the material being fed and a disc or guillotine valve 32 that is controlled electrically or with a mechanical system. The valves are operated alternately: when the first propul sor is full of material, the upper valve 31 closes and the bottom valve 32 opens and the material falls into the tube 33 , where it is the compressed air via the hollow rod 2 in the to be solidified Floor material presses. A valve 34 acts as a decompressor for each propulsor. The binding mixture forms a homogeneous paste with the already broken soil material, the hydration processes being guaranteed by the water that is naturally contained in the soil material or that was supplied during the phase of inserting the soil breaker tool as described above.

In summary, the invention sees a system and a unit for solidifying floor columns by forced immission of inert elements that can be granular, mainly Sand or fine gravel, and solidifying agents and fluids and ter use of pipes arranged in the penetration rod are the lower end for crushing and removing the Bo dens serves and thus solidified for the column from dry Soil prepared while pulling out the rod he will hold.

Claims (6)

1. System and unit for solidifying columns (piles) of soil material by forced immission of inert materials, which can be granular, mainly sand or gravel, and dry hardening agents, with an penetration rod ( 2 ), the inside pipes ( 8 ) for the forced immissions of the hardening binders and a pipe ( 9 ) for forced immissions of fluids, as well as an integral tool ( 3 ) at the lower end of the rod ( 2 ), provided with cutters for removing and breaking up the soil material and for making a hole with a diameter that corresponds to the width of the tool, characterized in that granular materials, essentially sand or gravel, and solidifying agents and fluids according to the nature of the soil material via pipes inside the rod ( 2 ), forcibly by means of shear means or Propulsors ( 23 ) are injected into the soil material. 2. System according to claim 1, characterized in that the rod ( 2 ) for penetration into the soil material can be polygonal or circular in section. 3. System according to claim 1, characterized in that the cutting edges of the tool ( 3 ) have a slight inclination with respect to the horizontal plane. 4. System according to claim 1, characterized in that the outlets ( 21 , 10 and 11 ) through which the hardening materials and the fluids are passed are arranged radially in order to optimal amalamation (mixing) of the hardening materials with the soil material to reach. 5. System according to any one of the preceding claims, characterized in that the completion and consolidation of the pile (column) of soil material ( 22 ) is achieved during the phase of retracting the penetration rod ( 2 ). 6. Unit according to one of the preceding claims, characterized by the following steps:

• a) Storage in dense silos of the granular and / or thread-like additional materials and the powdery binders;
• b) Transporting the above-mentioned materials in a predetermined amount of material necessary to obtain a solidified column, by means of separate screw conveyors, to a feeder equipped with a scale and equipment for determining and recording the load and the dosages the granular and powdery materials;
• c) Transport and immission by means of screw conveyors of the inert granular materials and solidifying agents in cylindrical or truncated cone-shaped pressure propulsors, which are equipped with leak-free upper and lower valves, which are actuated electro-pneumatically, and with valves for decompression of the interior of the propulsor when the material is being discharged as ;
• d) Transport of the above materials by means of tubes to outlet openings which are arranged according to the comminution mixing tool, by means of compressed air which has been cooled and dried for special use.