NO138035B - PROCEDURES AND APPARATUS FOR IMPROVING BREEDING REASONS - Google Patents

Abstract

Procedure and apparatus for improving the load-bearing capacity of loose soil.

Description

The present invention relates to a method

and an apparatus for the improvement of loose soil, i.e. damp, wet, clayey and/or industrially polluted ground and foundations, hereinafter referred to as "loose soil" for the sake of simplicity. During the treatment, the loose soil is mixed with various types of stabilizing substances, so that a mixture of the loose soil and the stabilizing substances is produced which results in the soil having an improved bearing capacity, so that it can be used in connection with foundation and foundation construction works.

The mixing of the stabilizing substances and the loose soil is carried out in a conventional way by introducing the stabilizing substance into a hollow cylinder which is designed to penetrate into the sedimentary layers of the soil, and whose lower part is connected with a pipe blade or the like, for mixing stabilizing substance fat and loose soil, or for example by inserting a rod into an already drilled, elongated hole, after which stabilizing substances can be injected under high pressure into the loose soil through a jet nozzle arranged on the front end of the rod.

However, known methods and devices for this purpose are affected by various disadvantages and shortcomings. In the first-mentioned case, stabilizers must be used in solid form, and it is then associated with difficulties to achieve a uniform mixture, and furthermore to ensure control of the state of the mixture before the mixing process is finished. In the second above-mentioned case, stabilizers must be used which are in liquid form, in contrast to the first-mentioned case, and it is likewise then. associated with difficulties in achieving a uniform mixture, as well as in controlling the condition of the mixture before the mixing process is finished. Furthermore, the mixed product tends to vary Independence of the quality of the loose soil.

The main purpose of the present invention is thus "to provide an improved method for" improving "/"the bearing capacity of the loose soil. of the stabilizing substances and the loose soil, regardless of the mixing ratio between the stabilizing substance and the loose soil.

A further purpose is to provide an efficient apparatus for carrying out the method, in particular an apparatus which enables uninterrupted monitoring of the mixing ratio between the stabilizing substance and the loose soil, as well as the quality of the mixture.

The method according to the invention is of the type where stabilizing substances are added to the loose soil, as mentioned, and where means are used to remove untreated loose soil from the surrounding soil for treatment, which means include a suction device and a removable guide device, such as a pipeline running from the loose soil to the suction device, a supply of stabilization material f for the supply of stabilization material necessary for the treatment of untreated loose soil removed by the removal device, a mixing device connected to the removal device and the supply of stabilization material for mixing untreated loose soil with the stabilization material for the production of soil with improved load-bearing properties, as well as a pressure feeding device with a pump device that is connected to the mixing device, a guide line being connected to the pump device to bring the treated soil back to the recording location, and the method according to the invention "characterize res by arranging one movable plate device on the ground in the area where the suction line is led down into the loose soil so that pressure can be applied via the plate device against the loose soil in the volume zone that surrounds the suction opening.

A preferred apparatus for carrying out the method is characterized by the fact that it includes a device comprising a tubular casing which is mounted on a carrier device to be able to be guided down into and up the loose soil, and by the fact that the plate device consists of a separator piston in the lower part of the suction line and by that the intake line is likewise mounted for movement up and down in the casing, and that another separator piston is mounted in the casing further below the intake line, which is supported by a tubular support rod that extends through the piston and is open to the underside of the piston, and that it. the tubular support rod is used for lowering treated loose soil which is sucked up from the underside of the piston through the suction line.

The essential novelty of the method according to the invention lies in the fact that one can remove, process and return loose soil in an efficient and controlled manner from a relatively limited volume of the soil to be treated.

The invention shall be described in more detail with reference to attached figures which, in connection with the description, illustrate how the method can be carried out, and further figures which show different types of apparatus with which the method can be carried out.

The drawings show:

Fig. 1 an apparatus for carrying out the method.

Fig. 2 shows a plan of the apparatus shown in fig. 1. Fig. 3 shows an enlarged vertical view showing the design of the lower part of the intake line, as well as the return pipe at a. device as shown in fig. 1. Fig. 4 shows a corresponding vertical view of the preferred embodiment of a device for carrying out the method. Fig. 5 shows six different phases during the execution of the method. using the device according to the invention as shown in fig. 4. Figures 6, 7 and 8 illustrate the method of use for a device as shown in fig. 1. Fig. 9 is a diagram illustrating the implementation of the method using a modified version of an apparatus for the implementation of the method. Fig. 10 is a diagram showing a further embodiment of an apparatus in the execution of the method. Fig. 11 is a ground plan which, on an enlarged scale, illustrates a pipe grid suitable for use in connection with the method according to the invention.

Fig. 12 shows a total of five drawings of the apparatus shown on

fig. 10, and which illustrates different phases during the execution of the method.

Figures 13, 14 and 15 show examples of how loose soil volumes can be improved using the method according to the invention.

Fig. 16 shows a vertical section of the apparatus shown in fig. 3 while the appliance is in use. Fig.. 17 is again ;:&t. diagram showing four phases during the implementation of the method using an apparatus which, among other things, a. shown in fig. 12. Fig. 18 is a diagram illustrating the relationship between the elapsed number of days after the mixing process has ended and the strength of the resulting mixture.

As shown in fig. 1 is a loose soil suction line 11 which

is lowered into a loose soil layer 13, as well as a pipeline 12 for pressure feeding of a mixture of loose soil and stabilizer, connected respectively to a loose soil intake section 14 and a loose soil discharge section 15 which are united in a mixing device A of the ground level type.

This device A of ground level type comprises a feeder section 16 for stabilizer material and a mixer section 17, where the loose soil 13 which is sucked in by means of a pump placed in the loose soil suction section 14 or the loose soil suction line 11, is transported through the stabilizer feed section 16 to the mixer section 17, while the stabilizing substance which is supplied through a feed line 18 is transported from the feeder section 16 to the mixer section 17, after which the mixture 19 of stabilizing substance f and loose soil is ejected into the loose soil 13 through the pressure feed line 12 under the influence of the pressure feed section 15 or a pressure feed pump.

As can be seen from the floor plan according to fig. 2, the device A of ground level type comprises a spring-controlled fxemmater 20, a liquid box 21, a pump 22 for supplying a specific amount of water, a system 23 for supplying a specific amount of powder, and a mixer 24 for preparing the stabilizing substance.

A specific amount of stabilizing substance in powder form, delivered from the spring-controlled forward feeder 20, is introduced through the supply system 23 into the mixer 24, whereby the powdered stabilizing substance is converted into a slurry by mixing with water that is, by means of the pump 22 is supplied to the mixer 24 from the liquid vessel 21, after which the stabilization sludge is mixed with loose soil which is sucked into the mixer section 26 by means of the suction line 11, after which the mixture is ejected into the feed pipe 12 by means of an injection pump 27 which forms the main part of a pressure mat section.

A screen 28 in the form of a perforated plate for separating foreign bodies is.,, as shown in fig. 3, arranged at the lower opening of the loose soil suction line 11, while a cylindrical separator 29 of large diameter is connected to the lower part of the pressure feed line 12, so that the finished mixture ejected from the pressure feed line 12 is not again sucked into the loose soil suction line 11.

Fig. -4 shows the device according to the invention for carrying out the method. As can be seen, the device includes an outer jacket 30 of large diameter, in which a separator piston 31 is arranged at the lower part of the loose soil suction line 11

in the form of a flange which is movable in an upward and downward direction inside the casing 30, the pressure feeder line 12 being introduced through a drilled opening in the separator piston 31, while the lower part of the line 12 is connected to another separator piston 32 in form of a flange which is likewise arranged to be movable in an upward and downward direction inside the mantle 30.

In this case, the mantle 30 is placed in an upright position on the loose base 13, as shown at I in fig. 5, while the pressure feed pipe 12 is initially lowered deep into the loose foundation 13, as shown at II in fig. 5, after which the mantle 30 penetrates into the loose base layer 13 to be filled with loose base. The separator piston 32 is introduced into the casing 30, while another separator piston 31 is placed above and likewise in the casing 30. In this position, loose soil is sucked from the upper part of the casing 30 into the suction line 11 and transported to the mixing device A of ground level type, in which the loose soil is mixed with stabilizer, after which the mixture is pressure fed into the lower part of the mantle 30 via the pressure feed pipe 12, ---.which results in a gradual raising of the pressure feed pipe 12 together with the separator piston. 32, after which the mantle 30, after being filled with the mixture 19, as shown at V in fig. 5, is subtracted up of the loose foundation 13 and thereby leaves a solid mixture in the form of a pillar.. The separator piston 31 should in this case . is attached to the upper part of the mantle 30.

According to fig. 6 becomes the loose ground. 13. which by means of a conveyor 34 is brought out from a factory 33, stored in a magazine section 35 and then sucked in through the suction line 11 for subsequent mixing with<*>stabilizing substance in the device A of ground level type, after which the prepared mixture is transported on a truck 36 to various construction sites for use in various ground reinforcement works.

As shown in fig. 7, the flowing mixture from the pressure feed pipe 12 is taken up in a mold 3 7 to be converted into blocks for use in road construction, land reclamation work, etc.

As can be seen from fig. 8, the magazine section 35 is divided into two compartments by means of a plate, where the loose soil 13 in one compartment is fed into the device A of ground level type and mixed with a stabilizing agent, after which the finished mixture is returned to the magazine section 35 and thereby flows into the other department.

In contrast to the previously shown examples of mixing using the device A of the ground level type after the loose soil has been sucked into the device, fig. 9 example of mixing in a device B of underground type which is lowered into a loose base layer.

The underground device B according to fig. 9 comprises a suction and pressure feeder section 51 with an inlet opening 52, as well as a low discharge opening 53, which is connected to a supply section 55 which is located above a mixer section 54 which is provided with an outlet 56 which opens downwards in a position below the suction and the pressure feeder section's 51 inlet opening .52. A pipeline 58 for the supply of stabilizing substance is further connected to the upper part of the supply section 55, so that the loose soil 59 which is sucked into the suction and pressure feeder section 51 through the inlet opening 52 and which flows out from the outlet opening 53 to be conveyed through the supply section 55 to the mixer section 54 , is thereby mixed with the stabilizer that is supplied from the pipeline 58 to the mixer section 54 via the supply section 55, after which the finished mixture 60 is carried out of the mixer section 54 through the outlet 56.

Fig. 10 shows an embodiment of the underground system B which is provided with a "pump 61, which forms an integral part of the suction and pressure feeder section 51 and which in this case is arranged in the form of a unique construction, named

"MOHNO system"..

This MOHNO system pump is characterized by a pumping effect which is produced by changing the capacity on the inlet side and the outlet side, as these two sides are thereby completely separated from each other by means of a sealing element with movement along a line of contact between an internal screw thread on the inner side of a stator 62 and an external screw passage on the outer side of a rotor 63, where this rotor 63 is brought into rotation by a motor 65 via a connecting rod 64, and where the rotor 63 is introduced into the elastic stator 62 which is enclosed of the cylindrical pump housing. The pump, which delivers a suction pressure of 700-750 mm Hg and a pressure of 10-24 kg/cm<2>, can easily transport even very sticky material and also transport clay with a water content of 70 to 80%. The pump is equipped with a waterproof, electrically or hydraulically driven motor 65 which is designed for operation in water. The MOHNO system pump is thus well suited for suction and pressure feeding of loose soil, but it is of course possible to use other pump types for the same purpose.

The pump 61, with its downward-directed inlet 66, is fixed in a vertical position to the lower end part of an intruder pipe 67, while the pipe 67 is equipped with a depressor device 68 at the upper end and is raised by means of a crane 79.: An outlet 69 at the upper end of the pump 61 is in communication with the upper inlet of a supply section 71 at the upper end of a mixer 70 which forms the main part of a mixer six ion. The pipeline blower 70 is of the stationary system type and provided with a large number of divided elements 72, which are enclosed in a hollow cylinder which is mounted in the mixer. The supply section 71 of the mixer 70 is connected to a flexible and pressure-resistant pipeline 73 for the pressurized supply of stabilizing substance f, the pipeline 73 being likewise connected to a device

ning 74~on the field for pressure feeding of.stabilizing material. The device 74, which consists of. an injection pump,. as well as a _ jnotor etc. 1. , --uses the pump 61 for. pressure feeding of stabilizing agent through the pipeline 73 to the supply section 71.

The stabilizing substance, which is advanced under pressure from the line 73 to the supply section 71, will consequently flow through the elements 72 in the mixer 70 together with the flowing loose soil from the outlet 69 of the pump 61, whereby the stabilizing substance and the loose soil are completely mixed before they leave the mixer 70 through the lower outlet. The above-mentioned process can also be carried out using a continuously running, motor-driven mixer or kneader.

At the outlet in the lower end part, the mixer 70 is provided with a screen 75 which prevents the mixture flowing out from the mixer 70 from being sucked into the inlet 66 of the pump 61. In place of the screen 75, a stirring grid 76 can be arranged which is fitted between the pump 61 and the mixer 70 and which is provided with openings 77 and 78 for the pump 61 and the mixer 70, and which by moving facilitates the suction of loose soil immediately around the pump 61 inlet 66.

As shown in fig. 12, the above-mentioned device B is of the underground type, installed on a loose soil 59 and, by operating the depressor device 68, lowered to the necessary depth in the loose soil, as shown at II and III in fig. 12, with simultaneous activation of the pump 61 and the device 74 for conveying stabilizing substance under pressure through the pressure feeder line 73 to the supply section 71. The loose soil which is sucked in by the pump 61 and which flows out from the outlet 69 is likewise conveyed under pressure to the supply section 71 whereby the loose soil, as it flows through the elements 72, is mixed with the stabilizing agent into a practically complete mixture which is then ejected into the loose base from the lower part of the shield 75, so that the mixture forms a solid pillar 80 as a result of the gradual raising of the underground device B, as shown at IV

on fig. 12.

The raising of the underground device B to ground level, as shown at V in fig. 12, will consequently result in the formation of a solid pillar 80 of the mixture extending upwards to ground level. It is of course unnecessary for the underground device B to be connected to the pressure device 68, if the loose base 58 is so soft that the underground device B can penetrate by its own weight.

In the above-mentioned process, the volume amount of the mixture of loose soil and stabilizer can be checked on the field by connecting a waterproof, electromagnetic current meter at the inlet of the mixer 70 and the outlet of the pressure feeder device 74, respectively. The resistance in the ground can also be estimated by measuring the outflow pressure at the outlet of the mixer.70. Furthermore, the depth of penetration of the underground device B can be checked and likewise recorded using a depth indicator in cooperation with the rotational movement of a self-synchronizing motor, where the motor's revolutions are dependent on the depth of penetration and where the motor is connected to a wire by means of a disk block, one end of which is anchored to the press-down device, etc. The fixed pillar 80 of the mixture can further be converted into circular, square or any other shape by the necessary change of . the screen's 75 horizontal part.

A larger number of the fixed pillars 80 produced by the above-mentioned process can be placed side by side with a certain mutual space as shown in Fig. 13, or in immediate contact with each other, as shown in Fig. 14. An artificial foundation reinforcement can also be produced by connecting a number of the fixed pillars of limited length, which are formed in the loose foundation 59, at the lower part thereof.

Fig. 16 shows a suction and pressure feeder device C for the third application case consisting of a MOHNO system pump 82, a motor 83 and a sliding plate 84. The MOHNO system pump 82 and the motor 83 are identical to the MOHNO system pump 61 and the motor 65 which is described in connection with the second application example, and the pump 82 is provided with a screen 85 for separating foreign bodies at the lower end of the screen. The sliding plate 84, which can be of any horizontal shape, is provided in the middle part with an opening 86 for receiving the pump's 82 cylindrical outer housing.

The underground device B is in position i according to fig. 17 shown placed on the loose base layer 87 with the sliding plate 84 placed against the loose base layer 87, while the pump 82 in position 11 is shown deep down in the loose base layer 87 and thereby, when the motor 83 is started, causes suction of loose base layer 8-7- through the inlet at the lower pump end, as well as pressure feeding of loose soil 76 through the outlet 88 and into the device A of the ground level type, - as shown "on "fig. 1, "in which the loose soil 87 is mixed with stabilizing substance f, after which the finished mixture is used in different ways, as described above. During the above-mentioned suction of loose soil, the sliding plate 84 will be displaced along the cylindrical outer housing of the pump 82 and thereby effect an almost complete suction of loose soil at the lower edge of the sliding plate 84, since the sliding plate 84 has a weight that is adapted to exert the necessary downward pressure. As a result of its weight, the sliding plate 84 will be lowered when the loose soil around the lower part of the pump 82 is sucked in by the pump 82, which prevents the formation of a cavity at the lower end of the pump 82 and contributes to the complete suction of loose soil by the pump 82. The sliding plate 84 can likewise be mounted on the vertical part of the suction line 11, as shown in Fig. 1.

In the above-mentioned cases, the necessary stabilizing substance can consist of lime and cement, sodium silicate or Jcalium silicate, as well as high polymer material, provided that these substances are used in the form of slurry.

The stabilizers are divided into the following groups: 1. The cement slurry group (with a weight ratio between cement and water of 2 -1).

2. The lime mud group.

3. Water-granulated slag with alkaline-acting sludge. 4. Binding material of sodium or potassium silicate (water glass).

5. Binding material of the equation group.

6. Binding material of the high polymer group.

7. Other.

The above stabilizer groups should be used in different mixtures in accordance with the condition or characteristics of the loose soil, the predetermined use of the mixture and the prevailing conditions at the place of use of the mixture, etc., which is decisive for determining the mixing ratio between stabilizer and loose soil. - The result of an experimental application of the mixture produced by the process according to the invention-. later, is shown by the diagram in fig. 18., where the vertical axis represents the uniaxial compressive strength, and the horizontal axis represents the elapsed number of days after the date of the experiment.

The diagram's curves show different mixing ratios such as

stated in the below-:

Curve 91 (in the case of muddy groundwater): Water content (weight ratio) 43.7%, stabilizer f (weight ratio), cement:water = 2^1, mixing ratio (weight ratio) 10%.

Curve 92 (in case of soft, clayey soil): Water content (weight ratio). 113%, stabilization foot (weight ratio), cement; water glass: water = 2:0, 1:1, mixing ratio (weight ratio) 20%.

Curve-93 (in case, of waste acid neutralized sludge): Water content (weight ratio) 333%, stabilizer (weight ratio) cement:water granulated slag:water =1:1:1, mixing ratio (weight ratio) 30%.

Claims (2)

1. Procedure for improving the load-bearing capacity of loose soil, such as moist, sandy and/or clay-containing soil or soil, so that the soil can be used as a base for foundation work or the like, where stabilization substances are added to the loose soil and where means are used to remove untreated loose soil from the surrounding soil for treatment, which means include a suction device and a removable guide device, such as a pipeline running from the loose soil to the suction device, a supply of stabilizing substance for the supply of stabilizing substance f necessary for the treatment of untreated loose soil which is removed by the removal device, a mixing device which is connected to the removal device and the supply for stabilization substance f for mixing untreated loose soil with stabilization substance fat for the production of soil with improved bearing properties, as well as a pressure feeding device with a pump device which is connected to the mixing device, a guide line being connected to the pumping device to bring the treated soil back to the recording site, characterized by the fact that a movable plate device is arranged on the soil in the area where the suction line is led down into the loose soil so that via the plate device a pressure can be applied to the loose soil in the volume zone that surrounds the suction opening. 2. Apparatus for carrying out the method as stated in claim 1, characterized in that the device comprises a tubular casing (30) which is mounted on a support device in order to be guided down into and up the loose soil, and in that the plate device consists of a separator piston ( 31) at the lower end of the intake line (11) and by the fact that the intake line is likewise mounted for movement up and down in the mantle (30), and by the fact that in the mantle further below the intake line another separator piston (32) is mounted which is carried by a tubular support rod that extends through the piston (31) and is open to the underside of the piston (32), and in that the tubular support rod is utilized for lowering treated loose soil that has been sucked up from the underside of the piston (31) through the suction line (11) ).