KR101038895B1 - Apparatus making mixed soil with air form and cement, method manufacturing it, and method construction thereof - Google Patents

Abstract

PURPOSE: A mixed soil manufacturing device is provided to simplify the manufacturing process of the slurry, to calculate the density of the slurry automatically, and to calculate the goal intensity of the mixed soil by measuring the density of the goal slurry accurately because the feed pressure of the slurry can be even by depot. CONSTITUTION: The mixed soil manufacturing device includes: a first mixer that loosen the field picking soil by using the agitating blade and make into the first slurry; a second mixer; a water tub; a solidifying agent storage tank; a first controller which automatically calculates the density of the first slurry by receiving the information measured in the weight transducer and volumemeter of the first mixer; the second controller which controls a series of process of making the third slurry after throwing the calculated solidifying agent by opening the valve of the solidifying agent storage tank after automatically calculating the solidifying agene input according to density and volume of the second slurry after making the second slurry arranged the density of the first slurry to the density inputted to MICOM(microcomputer) by adding the water to the second mixer by opening the valve of cistern when the density of the first slurry received from the first controller is higher than the density inputted to the MICOM ; a depot temporary-saving the third slurry provided in the second mixer; a main pressure eulogy pump; a bubble generator for supplying the bubble to the third slurry; and a bubble mixer.

Description

Apparatus making mixed soil with air form and cement, Method manufacturing it, and method construction

The present invention relates to the manufacture of mixed soil by mixing solidified fire and air bubbles in the field collecting soil collected from the field, in particular, the addition amount of water, solidified fire input, and the water content according to the water condition (water content) The present invention relates to a mixed soil production apparatus in which bubbles and solidified materials are mixed, which can automatically and automatically adjust the target density of the mixed soil by automatically calculating the bubble supply amount, and the mixed soil production method.

More specifically, the field collecting soil is released from the first stirrer to form a slurry, the weight and volume are measured, and the first controller calculates the density, transfers the slurry to the second stirrer, stirs, and simultaneously calculates the density. When the density is higher than the density previously input to the second controller, the water is added to the target density, and the second controller sets the input amount of the solidified material according to the weight, volume, and density of the slurry, and mixes the solidified material. The injected slurry is discharged at a constant pressure in the storage tank to be transported, and after mixing air bubbles in the transferred slurry, the density of the slurry is measured and checked with a density meter in the final step, so that the target density of the mixed soil can be automatically and accurately adjusted. To ensure that

Generally, when the soil is soft, such as a fill place or a backfill place, a slurry made by mixing solid fire and air bubbles in a field collecting soil collected at the site is filled with a soft place. It is a reaction method to stabilize the soil properties by using the construction method to improve the soft ground.

Thus, there is a patent registration No. 10-901107 as a conventional manufacturing method for producing a mixed soil to stabilize the soft ground.

The conventional mixed soil manufacturing method, the bubble mixing treatment soil manufacturing method, (a) mixing the soil and water to make a slurry; (b) mixing cement with the slurry in an amount determined according to the formula q _u28 = A x B ^-2.12 , and adding soluble silicate, bentonite or lime to the slurry; (c) mixing a foaming agent in the cement mixed slurry, wherein q _u28 is 28 days uniaxial compressive strength (kPA), A is a proportionality constant, and B is a material coefficient. .

However, the conventional mixed soil production method is determined by the water content and cement bubble content according to q _u28 = A × B ^-2.12 formula, the production method according to the formula is characterized in that the water condition (moisture) Content) is different, it is not possible to present a condition that can adjust the water content according to the target density or target strength of the mixed soil to be prepared in advance during the site construction, accordingly, there was a disadvantage that it is difficult to manufacture the mixed soil according to the target strength.

Accordingly, the present invention is to solve the various problems according to the conventional slurry production as described above, the purpose is to automatically add the amount of soil or water, the amount of solidified fire, and the amount of air bubble supply, etc., depending on the functional conditions of the field collected soil in the process of manufacturing mixed soil The present invention provides a mixed soil manufacturing apparatus in which a bubble and a solid material are mixed, and a mixed soil manufacturing method, which can calculate the target density of the mixed soil simply and automatically by calculation.

The mixed soil production apparatus mixed with bubbles and solidified materials for achieving the above object, by using a stirring blade to rotate the input field collecting soil to make the first slurry, the weight and volume of the released primary slurry can be measured A primary stirrer equipped with a weighing unit and a volume meter to ensure that it is equipped with a weighing device;

The weight of the secondary slurry is connected to the primary stirrer and the pipe, and stirred by using a stirring blade to rotate the primary slurry supplied from the primary stirrer, water is added to the primary slurry and stirred A secondary stirrer equipped with a weighing device and a volumetric device for measuring the volume and volume;

A first pressure pump installed between the primary stirrer and the secondary stirrer to supply the primary slurry of the primary stirrer to the secondary stirrer;

A water tank connected to the secondary stirrer and pipes to supply and block water to the secondary stirrer by opening and closing a valve;

A solid fire storage tank connected to the secondary stirrer and a pipe so as to supply and block the solid fire to the secondary stirrer by opening and closing a valve;

A first controller for automatically calculating the density of the first slurry by receiving the information measured by the weight measuring device and the volume measuring device of the first stirrer;

It is electrically connected to receive information from the first controller, and compares the density inputted to the microcomputer with the density of the primary slurry received from the first controller. After opening the water to the secondary stirrer to make the secondary slurry according to the density of the primary slurry to the density input to the microcomputer, and automatically calculates the amount of solidified fire according to the density and volume of the secondary slurry A second controller for controlling a series of processes for forming a third slurry by injecting a calculated amount of solid fire into the secondary slurry by opening the valve of the solid fire storage tank;

A storage tank connected to the secondary stirrer and a pipe and temporarily storing the tertiary slurry supplied from the secondary stirrer;

A second pressure pump installed between the secondary stirrer and the storage tank to supply a third slurry to the storage tank;

A main pressure pump installed in a pipe connected to the storage tank to supply the tertiary slurry stored in the storage tank to a city factory and pumping the tertiary slurry;

A bubble generator for supplying bubbles to the tertiary slurry transported by the main pressure pump;

A bubble mixer for mixing the bubbles made in the bubble generator with a third slurry supplied to a city factory after being discharged from the main pressure pump; And

It includes; a density meter for measuring the density of the fourth slurry is bubbled by the bubble mixer and supplied to the factory.

Method for producing a mixed soil mixed with bubbles and solidified material for achieving the above object, the step of making the first slurry by injecting the field collecting soil into the first stirrer to loosen the rotating stirring blade;

A weighing unit and a volume meter installed in a first stirrer measuring the weight and volume of the first slurry, and the first controller receiving the measured information to calculate the density of the first slurry;

The first slurry supplied from the primary stirrer to the secondary stirrer by the first pressure pump was stirred by using a stirring blade to rotate, and the second controller received the density inputted to the microcomputer and the first slurry received from the first controller. Comparing the density of the first slurry to make the secondary slurry when the density of the primary slurry is higher by adding water to the secondary stirrer to match the density of the primary slurry to the density input to the microcomputer;

Under the control of the second controller, the weight and volume of the secondary slurry are measured by the weighing unit and the volume meter to calculate the density, and the solidified material is automatically calculated based on the measured density and volume of the secondary slurry. Opening the valve of the storage tank, adding the calculated amount of solidified material to the secondary slurry, and then mixing the mixture to make a third slurry;

Supplying a tertiary slurry stored in the secondary stirrer to a storage tank by using a second pressure pump;

Supplying the third slurry stored in the storage tank to a city factory using a main pressure pump;

Supplying the high-pressure bubbles produced by the bubble generator to the bubble mixer and mixing the bubbles with the third slurry supplied to the city factory through the bubble mixer to form a fourth slurry; And

And mixing the bubbles by the bubble mixer to measure the density of the fourth slurry supplied to the factory using a density meter.

The present invention is because the first controller automatically calculates the density of the primary slurry while releasing the field collecting soil in the primary stirrer to make the primary slurry, before the primary slurry is supplied to the secondary stirrer beforehand Since the amount of water to be hydrolyzed is automatically determined by the second controller, this process is carried out in a continuous operation has the advantage of simplifying the manufacturing process of the slurry.

Above all, the present invention can automatically calculate the density of the slurry, as well as to uniformize the supply pressure of the slurry by the storage tank, so that the target strength of the mixed soil can be calculated by accurately measuring the density of the target slurry. have.

Furthermore, the present invention has the advantage that the main pressure pump and the bubble generator can be accommodated in one housing to reduce the volume and simplify the transportation.

1 is a mixed soil production apparatus mixed with bubbles and solidified materials according to the present invention
2 is a conceptual view showing another embodiment of the stirrer according to the present invention
Figure 3 is a flow chart of a mixed soil production method mixed with bubbles and solidified materials according to the present invention
Figure 4 is a flow chart of a mixed soil construction method mixed with bubbles and solidified materials according to the present invention

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the mixed soil production apparatus mixed with the bubble and solidified material according to the present invention, a mixed soil construction method for constructing the mixed soil.

As can be seen in the drawings, the mixed soil production apparatus mixed with the bubble and solidified material according to the present invention, the primary stirrer (1), the primary stirrer (1) to make a large input on-site mining soil Secondary stirrer 2 to make the supplied primary slurry into secondary and third slurry, a first pressure pump (P1) for supplying the primary slurry of the primary stirrer (1) to the secondary stirrer (2), the A water tank (WT) for supplying and blocking water to the secondary stirrer (2), a solid fire storage tank (CT) for supplying and blocking solid fire to the secondary stirrer (2), the density of the primary slurry automatically calculated The first controller (C1) to compare the density input to the microcomputer and the primary slurry received from the first controller (C1) when the density of the primary slurry is higher than the water tank (WT) and solid fire storage tank A second controller (C2) for controlling a series of processes of opening (CT) to inject water and solidified materials into the secondary slurry, and the secondary Storage tank (3) for storing the third slurry supplied from the semi-annuclear (2) to discharge the third slurry at the same pressure, second pressure pump (P2) for supplying the third slurry to the storage tank (3), the storage tank ( 3) a main pressure pump 4 for feeding the third slurry stored in the third slurry, a bubble generator 5 for supplying bubbles to the third slurry transported by the main pressure pump 4, and the bubble generator 5 It includes; bubble mixture (6) to make the fourth slurry by mixing the bubbles made in the third slurry in the transport.

In addition, the present invention further includes a density meter (7) for measuring the density of the quaternary slurry supplied to the factory by mixing the bubbles by the bubble mixer (6).

The primary stirrer (1) is to store the field picking soil collected in the field, it is configured in a tank shape, the stirring blade (1a) is rotated by a motor (M) to agitate the field picking soil is mounted On the bottom, a weighing device 1b is installed to measure the weight of the primary slurry released by the stirring blade 1a, and the volume meter 1c to measure the volume of the primary slurry on the inner side. Is installed.

1 and 2, the first and second stirrers (1) and (2) are shown.

The primary stirrer 1 may be manufactured in various forms, and in FIG. 1, a motor M for rotating the stirring blade 1a is installed at a lower side or a side thereof, and in FIG. 2, the motor M is at the side surface. It is installed in the shaft of the motor (M), a plurality of stirring blades (1a) is installed to cross and is configured to be able to rotate at the same time.

The volume measuring device 1c may be configured in various forms. As an example, a ruler capable of visually confirming the storage height of the primary slurry and a sensor for automatically detecting the storage height may be used. .

The weight measuring device 1b preferably measures the weight of the primary slurry based on the zero point in the state excluding the tank weight.

Knowing the area of the storage compartment of the primary stirrer 1 and the storage height of the accommodated primary slurry, the volumetric instrument 1c can simply obtain the volume of the primary slurry by multiplying them.

Therefore, the first controller C1 multiplies the measured height of the primary slurry measured by the volume measuring device 1c with the inputted information in the state in which the area of the primary stirrer 1 is previously input to the microcomputer. The density is automatically calculated and sent to the second controller C2 described later.

The secondary stirrer 2 is connected to the primary stirrer 1 by a pipe and stores the primary slurry supplied by the first pressure pump P1 installed in the pipe. The secondary stirrer 2 has a stirring blade 2a, a weighing machine 2b, and a volume measuring device 2c, which are rotated by a motor M, like the primary stirrer 1, and their structure and function. Since the same as the primary stirrer (1), a detailed description thereof will be omitted.

The first pressure pump (P1) is installed in the pipe connecting the first and second stirrers (1, 2) as can be seen in the drawing, the first slurry released from the first stirrer (1), the second stirrer ( It is good to use hydraulic pump as it functions to pump in 2).

The water tank (WT) is connected to the storage chamber of the secondary stirrer (2) and supplies water stored therein to the secondary stirrer (2). The water tank (WT) is provided with a valve (V1) to be supplied to and shut off the secondary stirrer (2), the valve (V1) uses an automatic valve that is automatically opened and closed by the control of the second controller (C2). Do it.

The solid fire storage tank (CT) is connected to the storage chamber of the secondary stirrer (2) and supplies the solidified material stored therein to the secondary stirrer (2). The valve (V2) is installed to supply and cut off the solidified fire filled in the secondary stirrer (2), the automatic valve is automatically opened and closed by the control of the second controller (C2).

Here, the solidified material filled in the solidified storage tank (CT) may be a general-purpose cement used in the market or a special cement manufactured for the purpose of use.

The first controller C1 is connected to the second controller C2 so as to provide the calculated information to the second controller C2. For this purpose, the first controller C1 is electrically connected or receivably connected to wireless communication. . The first controller C1 visually measures the weight and volume of the primary slurry measured by the weighing machine 1b and the volumetric meter 1c of the primary stirrer 1 and the density of the primary slurry calculated from these. It is preferable to indicate the numerical value on the display screen so that it can be confirmed.

The second controller C2 is connected in electrical or wireless communication so as to exchange information with the first controller C1. The second controller C2 receives information received from the first controller C1 and calculates the received information. All the information to be displayed, such as the amount of water remaining in the water tank (WT) and the amount of fire remaining in the fire storage tank (CT), is preferably displayed on the display screen numerically.

In addition, the second controller C2 is electrically connected or wirelessly connected to the second controller C2 so that the measured information can be input to the weight measuring device 2b and the volume measuring device 2c of the secondary stirrer 2.

The second controller C2 compares the density input to the microcomputer with the density of the primary slurry received from the first controller C1, and when the density of the primary slurry is higher, the valve V1 of the water tank WT. ) To open water to the secondary stirrer (2) to make the secondary slurry according to the density of the primary slurry to the density input to the microcomputer. Thereafter, the amount of solidified material is automatically calculated according to the density and volume of the secondary slurry, the valve V2 of the solidified storage tank CT is opened, and the amount of solidified material is added to the secondary slurry. To control a series of processes for making tertiary slurry.

Here, when water is added to the secondary stirrer 2, the amount is supplied as the density of the primary slurry becomes higher, which is possible by setting the amount of water pre-hydrogenated in the microcomputer as much as the difference of the density of the primary slurry. Do.

Similarly, the supply amount of solidification stored in the solidification storage tank CT may be selectively adjusted by inputting the target solidification input to the microcomputer according to the correlation between the density and the volume of the secondary slurry.

The storage tank 3 is a very important element in the present invention to supply the third slurry to the bubble mixer 6 at the same pressure.

In other words, the storage tank 3 is configured such that the area of the inlet 3a is larger than the area of the outlet 3b, so that the third slurry is always filled with the inside of the storage tank 3. Therefore, when the main pressure pump 4 is driven to pump the third slurry filled in the storage tank 3 to the bubble mixer 6, the amount injected from the inlet 3a rather than the amount of the third slurry discharged from the outlet 3b. Since there are more, the inside of the storage tank 3 is always filled with the third slurry.

Therefore, since the pressure of the tertiary slurry supplied to the bubble mixer 6 becomes constant, the bubbles are uniformly mixed in the bubble mixer 6 so that the density of the fourth slurry is constant.

If there is no storage tank 3, the third slurry stored in the secondary stirrer 2 is pumped to the bubble mixer 6 by the power of the main pressure pump 4, and the three stored in the secondary stirrer 2 are stored. As the slurry is gradually lowered in height, the pressure is also lowered. Therefore, since the tertiary slurry being conveyed to the bubble mixer 6 has a lower pressure than the first one, the initial conveying speed is slower and the later conveying speed is faster, so that the tertiary slurry passing through the bubble mixer 6 is eventually passed. As the speed is changed, the bubble mixing ratio is also changed, and the density of the fourth slurry, that is, the mixed soil, which is discharged to the final factory is different, so that the target density cannot be met. Because of this problem, the storage tank 3 will be said to be an important component in constructing the present invention.

The second pressure pump (P2) is installed in the pipe connected to the outlet of the secondary stirrer (2) to supply the third slurry to the storage tank (3), a known one is used.

The main pump pump (4) is for discharging the third slurry stored in the storage tank (3) at a high pressure to the factory, it uses a larger than the discharge capacity of the first and second pressure pump (P1) (P2).

The main pump pump 4 is stored in one housing together with the bubble generator 5 to be described later is stored integrally. Therefore, since the main pressure pump 4 and the bubble generator 5 is located in the same place it has the advantage of convenient transport and handling.

The bubble generator (5) is for supplying bubbles to the tertiary slurry conveyed by the main pressure pump (4), a compressor for compressing air may be used.

The bubble mixer 6 supplies the bubbles made in the bubble generator 5 to the inside, so that the bubbles are mixed with the tertiary slurry introduced into the inside through the storage tank 3.

The bubble mixer (6) is configured in a tubular shape so that the third slurry introduced into the interior by the main pressure pump (4) can be smoothly conveyed, and the third channel slurry and the bubbles collide smoothly in the inner passage. The grid 6a is arranged so that it can be. A plurality of grids 6a are arranged in a row, and as shown in FIG. 1, the grids 6a having different positions of third grids passing through the grids 6a having different positions are different from each other. It is good to increase the mixing efficiency by passing through in the vortex or turbulent state while colliding.

That is, the plurality of lattice networks 6a are inconsistent when viewed in the advancing direction of the tertiary slurry so that the tertiary slurry colliding with them proceeds in a vortex or turbulent state.

More specifically, the first grid 6a is cross-shaped, the grid 6a located at the rear thereof is multiplied, and the grid 6a located at the rear thereof is again cross-shaped. If it is repeated, the tertiary slurry passing through these grids 6a alternately collides with the grids 6a sequentially, so that the bubbles flow in a vortex or turbulent state by irregular flow to mix the bubbles well.

On the other hand, the present invention is further equipped with a density meter (7) for measuring the density of the fourth slurry is mixed with bubbles by the bubble mixer (6) supplied to the factory. The density meter 7 uses a known one to measure the final density of the quaternary slurry passing through.

If the density of the fourth slurry measured by the density meter 7 is not constant, the second controller C2 senses this and shows the driving of the device of the present invention to find and solve the cause.

In the present invention configured as described above, the field picking soil is put into the primary stirrer 1 and then unwound to form a first slurry, after which the water is transported by the pumping pumps P1, P2, 4, and the second. Slurry and solidified materials are mixed to form tertiary slurry and quaternary slurry in which bubbles are mixed, that is, mixed soil, and then discharged to the factory. In this process, all the components are automatically driven by the control of the first and second controllers C1 and C2, and thus, the target density of the mixed soil can be accurately set, which is a beneficial occurrence.

The following describes a method for producing a mixed soil mixed with bubbles and solidified materials according to the present invention.

Mixing soil according to the present invention is a step (S1) to make a primary slurry by injecting a field collecting soil into the primary stirrer (1) to loosen the rotating stirring blade (1a);

Weighers 1b and volumetric instruments 1c installed in the primary stirrer 1 measure the weight and volume of the primary slurry, and the first controller C1 receives the measured information to determine the primary slurry. Calculating a density (S2);

The primary slurry supplied from the primary stirrer 1 to the secondary stirrer 2 by the first pressure pump P1 is stirred by using a stirring blade 2a that rotates, and the second controller C2 receives the microcomputer. Compare the density input to the density of the primary slurry received by the first controller (C1) and when the density of the primary slurry is higher, the water is added to the secondary stirrer (2) to the density of the primary slurry Making a secondary slurry according to the density input to the microcomputer (S3);

The density is calculated by measuring the weight and volume of the secondary slurry with the weighing machine 2b and the volumetric meter 2c under the control of the second controller C2, and according to the measured density and volume of the secondary slurry Step S4 of automatically calculating the fire input amount and then opening the valve V2 of the solid fire storage tank CT to inject the calculated amount of solid fire into the secondary slurry and mixing the mixture to form a third slurry;

Supplying the tertiary slurry stored in the secondary stirrer (2) to the storage tank (3) using a second pressure pump (P2);

Discharging the tertiary slurry stored in the storage tank (3) using the main pressure pump (S6); And

By supplying the tertiary slurry discharged from the storage tank (3) to the bubble mixer (6), by supplying a high-pressure bubble produced in the bubble generator (5) to the bubble mixer (6) to mix the bubbles in the tertiary slurry It includes; step (S7) to make the fourth slurry.

On the other hand, the construction site using the present invention in the construction site, the construction method for constructing the prepared mixed soil is as follows.

Putting the on-site collecting soil into the primary stirrer (1) to release the rotating stirring blade (1a) to make a primary slurry (S1-1);

Weighers 1b and volumetric instruments 1c installed in the primary stirrer 1 measure the weight and volume of the primary slurry, and the first controller C1 receives the measured information to determine the primary slurry. Calculating a density (S2-1);

The primary slurry supplied from the primary stirrer 1 to the secondary stirrer 2 by the first pressure pump P1 is stirred by using a stirring blade 2a that rotates, and the second controller C2 receives the microcomputer. Compare the density input to the density of the primary slurry received by the first controller (C1) and when the density of the primary slurry is higher, the water is added to the secondary stirrer (2) to the density of the primary slurry Making a second slurry according to the density input to the microcomputer (S3-1);

The density is calculated by measuring the weight and volume of the secondary slurry with the weighing machine 2b and the volumetric meter 2c under the control of the second controller C2, and according to the measured density and volume of the secondary slurry After automatically calculating the fire input amount, the valve (V2) of the fire storage tank (CT) is opened to inject the calculated amount of fire into the secondary slurry, followed by mixing to form the third slurry (S4-1). ;

Supplying the tertiary slurry stored in the secondary stirrer (2) to the storage tank (3) using a second pressure pump (P2) (S5-1);

Supplying the tertiary slurry stored in the storage tank (3) to a city factory using a main pressure pump (S6-1);

Supplying the high-pressure bubble produced in the bubble generator (5) to the bubble mixer (6) to mix the bubble to the tertiary slurry supplied to the factory factory through the bubble mixer (6) (S7-) One); And

And mixing the bubbles by the bubble mixer 6 to measure the density using the density meter 7 with the fourth slurry supplied to the factory factory (S8-1).

Descriptions related to the apparatus at each step of the mixed soil manufacturing process and construction method have been described in detail in the description of the apparatus already described, and thus those skilled in the art will understand the detailed description thereof.

In the manufacturing method, the field collecting soil will vary depending on the soil of the collecting site, and can be used as long as the field collecting soil can be hardened by solidified materials to achieve the object of the present invention.

On the other hand, the mixed soil mixed with the bubbles and the solidified material of the present invention can be realized by the manufacturing apparatus and the manufacturing method described above.

In addition, a mixed soil construction structure in which bubbles and solidified materials are mixed can be realized by the manufacturing apparatus and construction method described above.

1: 1st stirrer 2: 2nd stirrer
3: storage tank 4: main pump
5: bubble generator 6: bubble mixer
7: density meter

Claims (14)

A first stirrer equipped with a weighing device and a volume measuring device to measure the weight and volume of the released primary slurry by using the stirring blade to rotate the input field collecting soil;
It is agitation by using a stirring blade to rotate the primary slurry supplied from the primary stirrer, water and water to the primary slurry and stirred to measure the weight and volume of the secondary slurry prepared by stirring A secondary stirrer equipped with a volume meter;
A water tank connected to the secondary stirrer and pipes to supply and block water to the secondary stirrer by opening and closing a valve;
A solid fire storage tank connected to the secondary stirrer and a pipe so as to supply and block the solid fire to the secondary stirrer by opening and closing a valve;
A first controller for automatically calculating the density of the first slurry by receiving the information measured by the weight measuring device and the volume measuring device of the first stirrer;
It is electrically connected to receive information from the first controller, and compares the density inputted to the microcomputer with the density of the primary slurry received from the first controller. After opening the water to the secondary stirrer to make the secondary slurry according to the density of the primary slurry to the density input to the microcomputer, and automatically calculates the amount of solidified fire according to the density and volume of the secondary slurry A second controller for controlling a series of processes for forming a third slurry by injecting a calculated amount of solid fire into the secondary slurry by opening the valve of the solid fire storage tank;
A storage tank for temporarily storing the tertiary slurry supplied from the secondary stirrer;
A main pressure pump installed in a pipe connected to the storage tank to supply the tertiary slurry stored in the storage tank to a city factory and pumping the tertiary slurry;
A bubble generator for supplying bubbles to the tertiary slurry transported by the main pressure pump; And
And a bubble mixer for mixing the bubbles made by the bubble generator in a third slurry supplied to a city factory after being discharged from the main pressure pump.
A first stirrer equipped with a weighing device and a volume measuring device to measure the weight and volume of the released primary slurry by using the stirring blade to rotate the input field collecting soil;
It is agitation by using a stirring blade to rotate the primary slurry supplied from the primary stirrer, water and water to the primary slurry and stirred to measure the weight and volume of the secondary slurry prepared by stirring A secondary stirrer equipped with a volume meter;
A water tank connected to the secondary stirrer and pipes to supply and block water to the secondary stirrer by opening and closing a valve;
A solid fire storage tank connected to the secondary stirrer and a pipe so as to supply and block the solid fire to the secondary stirrer by opening and closing a valve;
A first controller for automatically calculating the density of the first slurry by receiving the information measured by the weight measuring device and the volume measuring device of the first stirrer;
It is electrically connected to receive information from the first controller, and compares the density inputted to the microcomputer with the density of the primary slurry received from the first controller. After opening the water to the secondary stirrer to make the secondary slurry according to the density of the primary slurry to the density input to the microcomputer, and automatically calculates the amount of solidified fire according to the density and volume of the secondary slurry A second controller for controlling a series of processes for forming a third slurry by injecting a calculated amount of solid fire into the secondary slurry by opening the valve of the solid fire storage tank;
A storage tank for temporarily storing the tertiary slurry supplied from the secondary stirrer;
A main pressure pump installed in a pipe connected to the storage tank to supply the tertiary slurry stored in the storage tank to a city factory and pumping the tertiary slurry;
A bubble generator for supplying bubbles to the tertiary slurry transported by the main pressure pump;
A bubble mixer for mixing the bubbles made in the bubble generator with a third slurry supplied to a city factory after being discharged from the main pressure pump; And
The mixed soil production apparatus mixed with the bubble and solidified material comprising a; a density meter for measuring the density of the fourth slurry is mixed with bubbles by the bubble mixer supplied to the factory.
The method of claim 1 or claim 2, wherein the primary stirrer is a first weighing device for measuring the weight of the primary slurry released from the tank lower; And
And a first volume measuring device installed inside the tank to measure the volume of the released primary slurry.
Here, the first weighing device and the first volume measuring device is a mixed soil production apparatus mixed with the bubble and solidified material, characterized in that connected to the first controller electrically or wirelessly to provide the measured information to the first controller.
The method of claim 1 or 2, wherein the secondary stirrer is a second weighing device installed in the lower tank so as to measure the weight of the secondary slurry and the third slurry;
And a second volumetric meter installed inside the tank to measure the volumes of the secondary slurry and the third slurry.
Here, the second weighing device and the second volume measuring device is a mixed soil production apparatus mixed with bubbles and solidified material that is electrically or wirelessly connected to the second controller to provide the measured information to the second controller.
The mixed soil production apparatus according to claim 1 or 2, wherein the main pump and the bubble generator are housed in a single housing.
According to claim 1 or 2, wherein the storage tank is equipped with a stirring blade that rotates by a motor to agitate the stored third slurry, the bubble and solidified material, characterized in that the inlet area is formed larger than the outlet area Mixed soil manufacturing equipment.
The method according to claim 1 or 2, wherein the primary stirrer and the secondary stirrer are connected by a pipe, the pipe is equipped with a first pressure pump for feeding the primary slurry;
The outlet of the secondary stirrer is connected to the pipe so as to guide the supply of the third slurry to the storage tank, the pipe is a second pressure pump for pumping the third slurry; bubble and solidified material characterized in that the Mixed Soil Maker.
The apparatus of claim 1, wherein the bubble mixer includes a lattice network disposed on the inner passage so that the tertiary slurry and the bubbles are smoothly mixed in the inner passage.
The method according to claim 8, wherein the plurality of grids are arranged in a row, each grid is a bubble and high, characterized in that the third slurry is in a vortex or turbulent state in a discordant view in the direction of the third slurry Mixed soil manufacturing apparatus mixed with fire.
Making a first slurry by injecting a field collecting soil into a first stirrer and releasing it with a rotating stirring blade;
A weighing unit and a volume meter installed in a first stirrer measuring the weight and volume of the first slurry, and the first controller receiving the measured information to calculate the density of the first slurry;
The first slurry fed from the first stirrer to the second stirrer was agitated by using a stirring blade to rotate, and the density of the first controller received by the first controller and the density of the first slurry received by the first controller were compared. If the density of the secondary slurry is higher, water is added to the secondary stirrer to make the secondary slurry according to the density of the primary slurry according to the density input to the microcomputer;
Under the control of the second controller, the weight and volume of the secondary slurry are measured by the weighing unit and the volume meter to calculate the density, and the solidified material is automatically calculated based on the measured density and volume of the secondary slurry. Opening the valve of the storage tank, adding the calculated amount of solidified material to the secondary slurry, and then mixing the mixture to make a third slurry;
Supplying a tertiary slurry stored in the secondary stirrer to a storage tank;
Discharging the third slurry stored in the storage tank by using a main pressure pump; And
Supplying the tertiary slurry discharged from the storage tank to the bubble mixer, and supplying the high-pressure bubbles produced by the bubble generator to the bubble mixer to mix the bubbles in the tertiary slurry to make the fourth slurry. Method of producing a mixed soil mixed with bubbles and solidified material.
The method of claim 10, further comprising: measuring the density of the fourth slurry produced by mixing the bubbles by the bubble mixer with a density meter using a density meter.
Making a first slurry by injecting a field collecting soil into a first stirrer and releasing it with a rotating stirring blade;
A weighing unit and a volume meter installed in a first stirrer measuring the weight and volume of the first slurry, and the first controller receiving the measured information to calculate the density of the first slurry;
The first slurry fed from the first stirrer to the second stirrer was agitated by using a stirring blade to rotate, and the density of the first controller received by the first controller and the density of the first slurry received by the first controller were compared. If the density of the secondary slurry is higher, water is added to the secondary stirrer to make the secondary slurry according to the density of the primary slurry according to the density input to the microcomputer;
Under the control of the second controller, the weight and volume of the secondary slurry are measured by the weighing unit and the volume meter to calculate the density, and the solidified material is automatically calculated based on the measured density and volume of the secondary slurry. Opening the valve of the storage tank, adding the calculated amount of solidified material to the secondary slurry, and then mixing the mixture to make a third slurry;
Supplying a tertiary slurry stored in the secondary stirrer to a storage tank;
Supplying the third slurry stored in the storage tank to a city factory using a main pressure pump;
Supplying the high-pressure bubbles produced by the bubble generator to the bubble mixer and mixing the bubbles with the third slurry supplied to the city factory through the bubble mixer to form a fourth slurry; And
And mixing the bubbles by the bubble mixer to measure the density of the fourth slurry supplied to the factory using a density meter. The method of claim 1, further comprising mixing the bubbles and the solidified material.
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