KR100516949B1 - Injecting method and device to multi-point ground - Google Patents

Abstract

The present invention is a multi-point ground injection method and apparatus for multi-injecting a ground improvement material into a ground such as soft ground, and in particular, the optimum injection to each layer at the same time or selectively for the ground where the ground situation is different for each layer Not only can it be achieved, it is also possible to make three-dimensional injection in the longitudinal and transverse directions in the ground, and to control the injection from a plurality of injection tubes arbitrarily, and to simultaneously inject through a plurality of injection tubes. Therefore, the multi-point ground injection method and apparatus improves the reliability of the penetration injection into the fine soil layer and also shortens the injection air by rapid construction.

In the above-described injection method, a plurality of injection pipes 8 having discharge ports 7 are embedded in a plurality of injection points 6 of the ground 1, and from the plurality of discharge ports 7 through the injection pipes 8. Multi-site injection method for multi-point injection of ground improvement material, which is equipped with a plurality of unit pumps (3, 3, 3) operated by independent driving sources (4) and controlled by a central management device (26). (5), a plurality of these unit pumps 3, 3... 3 are connected to the plurality of injection pipes 8, 8. 8 through the conduits 10, 10. By the operation of the unit pumps 3, 3... 3 of the ground improving material from the plurality of discharge ports 7, 7. 7 through the plurality of injection points 6, 6. The multi-point ground injection device A operates as a multi-point injection tank 2 for ground improvement material storage and an independent drive source 4 in one plant, and also as a centralized management device 26. A multi-injection injector 5 connected to a storage tank 2 having a plurality of controlled unit pumps 3, 3... 3, and a plurality of injection points 6, 6. ), Each of which has a plurality of injection pipes (8, 8 ... 8) each having an outlet (7) connected to each of the unit pumps (3, 3 ... 3) and the conduit (10). A plurality of independent unit pumps 3, 3. 3 are provided with a rotation speed transmission 25 controlled by the centralized management device 26, and a flow pressure detector 27 is provided in the conduit 10. In this way, the flow rate and / or pressure data signal from the flow rate pressure detector 27 is transmitted to the centralized management device 26, and the ground improving material in the tank 2 is transferred to each unit pump 3, 3. By injection into each injection tube 8, 8..., 8 at an arbitrary injection speed, injection pressure, or injection amount, and multi-point injection into the ground 1 simultaneously from a plurality of discharge ports 7, 7. It is composed.

Description

Injecting method and device to multi-point ground}

The present invention relates to a multi-point ground injection method and apparatus for multi-injecting a ground improvement material in a ground such as soft ground, in particular, the optimum injection to each of these layers at the same time, or for a ground where the ground situation is different for each layer, or Not only can it be achieved selectively, but also three-dimensional injection in the longitudinal direction and the transverse direction in the ground can be performed, and the injection from a plurality of injection tubes can be arbitrarily controlled, and at the same time through a plurality of injection tubes Therefore, the present invention relates to a multi-point ground injection method and apparatus which improves the reliability of penetration injection into the fine soil layer and also shortens the injection air by rapid construction.

Here, the ground reforming material is an injection material for solidifying the pollutants such as ground solidification injection material, industrial waste for strengthening or indexing the ground of soft ground, etc., and preventing the leakage of harmful substances from the pollutant. It refers to a solidified material for forming an index layer, an injection medicine containing a chemical for pollution-free pollution, or a heavy metal fixing material for chemically inactivating a thick metal.

Since the ground usually has different permeability coefficients and gap ratios for each layer, the ground situation is different for each layer. Conventionally, although not shown, the injection tube is inserted into the ground alone or at a plurality of intervals, and the injection material is sequentially moved upward or downward through the injection tubes. Injected.

By the way, the biggest problem in the injection of the chemical solution is the penetration into the fine sand layer having a small permeability coefficient or homogeneous penetration into the ground composed of other soil layers.

The water permeability to the fine sand layer is usually k = 10 ^-3 to 10 ^-4 cm / sec. Low pressure injection must be done with a low discharge rate of liters.

However, in the above known injection method, one set of injection pumps is used for one injection pipe. In such an injection method, from the economical efficiency of shortening the air as much as possible, the discharge amount of 10-20 liters per minute is inevitably reduced from the viewpoint of the performance limit of the pump, and the injection pressure is increased to cause the ground breakdown. For this reason, the soil is raised or the infiltration of fine soil layer is insufficient.

In the case of injection into the soil of other soil layers, it is practically difficult to change the injection speed or adjust the injection amount in response to the soil change when the soil layer changes, so that in some layers, the injection liquid diffuses in large quantities or A phenomenon such as small penetration into the layer occurs, and a problem arises in that the continuity between adjacent solid bodies cannot be obtained in such an injection state.

In addition, Japanese Patent Laid-Open No. 12-45259 is filed as a source by the present applicant. According to this, when a plurality of injection pipes are arranged in the ground and the ground improvement material is injected into the ground from each discharge port through the plurality of injection pipes, a plurality of unit pumps are provided in one plant, and the plurality of unit pumps is provided. Is pumped to each injection tube by a multi-extension pump operating simultaneously in one drive source, and injected into the ground from the discharge port.

In the above-mentioned known art, since the injection tubing requires a long distance from the pump plant to the injection hole, it is necessary to use an injection liquid having a long gel time with a low viscosity. However, the injection of long gel time cannot stop the injection because once it starts to deviate from the rough surface of the ground or the ground, the injection cannot be stopped, and in the meantime, the grout There was an unreasonable problem such as gelation.

In addition, since a plurality of unit pumps constituting the multi-extension pump are simultaneously driven by one drive source, the ground conditions at each discharge port are different, and therefore, even though the optimum injection conditions are different, all the unit pumps are the same condition. It was impossible to perform an optimal injection for each discharge port because of the drive of

Therefore, the object of the present invention, as described above, while taking advantage of the multi-point injection pump by low pressure penetration injection of the glass to the wide ground developed so far, corresponding to the injection situation of each glass injection pipe, It is possible to arbitrarily manage the injection speed, injection pressure, injection stop, resume, gelation time, etc. by each unit pump, and in addition, it is possible to manage the operation of a plurality of unit pumps at the same time, so that it is possible to grasp and manage the whole injection situation. It is to provide a multi-point ground injection method and apparatus that improves the drawbacks of the known art.

Further, another object of the present invention is to make it possible to prevent this by injecting a short gelling time in the case of roughness injection by primary injection or when the long gelling time of the glass starts to deviate during the injection. The present invention is to dramatically improve the practicality of multipoint injection by a continuous injection device.

In addition, another object of the present invention is to simultaneously or selectively perform optimal injection with a variable discharge amount of 1 liter or less to several liters / minute for a fine-grained soil layer having small water permeability or a ground having different ground conditions for each layer. In addition to this, three-dimensional injection in the longitudinal and transverse directions in the ground is also possible, which improves the reliability of penetration injection into the fine soil layer, and also shortens the injection air by rapid construction. To provide a multi-point ground injection method and apparatus that improves the shortcomings present in the technology.

In addition, the object of the present invention is not only a solution-type injection material, but also a suspension-type injection material that can be used, it is possible to select any injection corresponding to the ground situation for each injection point, the present invention known in the above-mentioned It is to provide a multi-point ground injection method and apparatus that improves the shortcomings.

In order to achieve the above object, according to the multi-point ground injection method of the present invention, a plurality of injection pipes having discharge ports are embedded at a plurality of injection points in the ground, and the ground improving material is simultaneously discharged from the plurality of discharge holes through these injection pipes. As a ground injection method to inject multiple points,

A multi-extension injection device having a plurality of unit pumps, each operating as an independent drive source and controlled by a central management device, is used, and the plurality of unit pumps are connected to the plurality of injection pipes through conduits, and the plurality of units It is characterized in that the ground improving material is injected from the plurality of discharge ports through a plurality of injection points in the ground by the operation of the pump.

In addition, in order to achieve the above object, according to the multi-point ground injection device of the present invention, a ground improvement material storage tank and a plurality of unit pumps operated as independent driving sources in each of the plants, and controlled by a central management device In addition, a plurality of injection pipes connected to the storage tank and a plurality of injection pipes each having a discharge port embedded in a plurality of injection points in the ground and connected to each of the unit pumps and conduits, And a rotation speed transmission each controlled by a centralized management device and a flow pressure detector in the conduit, thereby concentrating the signals of the flow rate and / or pressure data from the flow pressure detector. To the management device, and transfers the ground improving material in the tank to an arbitrary injection speed, injection pressure or injection amount by the operation of each unit pump. To characterized in that the pressure-fed to each filling pipe, and at the same time, multi-point injection into the ground from a plurality of discharge ports.

The above speed transmission is collectively controlled by the centralized management device. For this reason, many unit pumps have the function of injecting optimally to each injection point independently from one side, and comprise one injection | pouring apparatus which collectively manages the injection of many injection points as a whole on the other side.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail with reference to an accompanying drawing.

1 is an explanatory diagram showing a principle diagram of a device according to the present invention,

2 is a principle diagram of a piston pump generally used in the related art.

3 is a principle diagram of using one flanger pump as a unit pump,

4 is a sectional view of a specific example using a flanger pump as a unit pump,

5 is a cross-sectional view of a diaphragm used as the unit pump of the present invention,

6 is a cross-sectional view of the squeeze pump used as the unit pump of the present invention, wherein (a) to (d) are process diagrams showing an operating state, respectively;

7 is a cross-sectional view of the snack pump used in the unit pump of the present invention,

8 is a flow sheet of one embodiment of an apparatus according to the invention,

9 is a flow sheet of another embodiment of an apparatus according to the invention,

10 is a flow sheet of another embodiment of an apparatus according to the invention,

11 is a specific example displayed on the injection monitoring panel of the centralized management device,

12 is a flow sheet of another embodiment of the apparatus of the present invention using a plurality of tubules as an injection tube,

13 is a flow sheet of another embodiment of an apparatus according to the invention.

The multi-point ground injection device A according to the present invention shown in FIG. 1 operates as a ground improvement storage tank 2 and independent drive sources 4, 4 and 4, such as respective motors, in one plant, and is also a centralized management device. A multi-injection device 5 connected to each of the storage tanks 2 having a plurality of unit pumps 3, 3... 3 connected and controlled through the conduits 9, 9. , The discharge ports 7, 7... Which are embedded and disposed in the injection point 6 of the ground 1, respectively, via the unit pumps 3, 3. 3 and the conduits 10, 10. A plurality of injection pipes 8, 8... 8 having 7) are provided.

In addition, the above-mentioned independent unit pumps 3, 3... 3 are provided with rotation speed transmissions 25, 25... 25, such as inverters connected to the centralized management device 26 and controlled. Conduits 10, 10... 10 connecting the 3, 3... 3 and injection tubes 8, 8... 8 are respectively connected to the centralized management device 26 and controlled by the flow rate pressure. The detectors 27 and 27... 27 are provided. As the injection pipes 8, 8, 8, for example, a Y-shaped pipe rod is used.

With the above-described configuration, in the present invention, a signal of the flow rate and / or pressure data from the flow rate pressure detector 27 is transmitted to the centralized management device 26, and the ground improvement material in the tank 2 is transferred to each unit pump 3 ,. 3... Operation of the pump 3 to the respective injection pipes 8, 8. 8 at an arbitrary injection speed, injection pressure, or injection amount, and simultaneously the ground 1 from the plurality of discharge ports 7, 7. ), Multi-point injection into injection points 6, 6... 6 forms an injection zone 34.

As the unit pump 3 used for this invention, a piston pump, a flanger pump, a diaphragm pump, a squeeze pump, a neck pump, etc. are mentioned. All of these pumps are small except for the piston pump, they are also simple in structure, and furthermore, they are not easily broken, and therefore, not only liquid but also suspension-type glass can be used and are suitable as the unit pump of the present invention. In particular, the various pumps shown in Figs. 3 to 7 are small, light weight, low discharge pumps, and furthermore have low pulsation, simple structure, and do not easily cause breakdown. Therefore, not only a solution type improvement material but also a suspension type glass Woot is also available and is a unit pump suitable for the present invention.

2 is a principle diagram of the piston pump 68, which rotates with the rotation of the flanger 12 and the rotational shaft 15 connected to the flanger 12 via a piston rod 13 and a crankshaft 14. As described above, a large discharge amount is possible at high pressure, but the pulsation is large and the weight is large.

3 is a principle diagram of the unit pump 3 according to the present invention using the flanger pump 11. In FIG. 3, the flanger pump 11 is built so that the reciprocating motion is freely formed in the cylinder 18 in which the flanger 12 is filled with the grand packing 17, and the rotating shaft 15 is connected through the connecting rod 19. Is connected to the crank 16 which rotates with the rotation of the. The cylinder 18 is connected to the suction hose 21 and the delivery hose 22 through the conduit 20 at the bottom of the flanger 12.

Then, in the drive of the flanger pump 11, the crank 16 rotates together with the rotation of the rotary shaft 15 to push up the flanger 12, that is, upward. At this time, the ground improving material in the ground improving material storage tank 2 shown in FIG. 1 is sucked through the suction hose 21 of FIG. 3, and the ball valve 23 is pushed open to open the moving amount of the flanger 12. Only a considerable amount is drawn in, then the crank 16 rotates with the rotation of the rotational shaft 15 to lower the direction, ie downward, to recover the flanger 12. At this time, the ground improving material which is sucked is pressurized to close the ball valve 23, pushes the ball valve 24 open and is sent to the delivery hose 22, and the injection pipe through the conduit 10 of FIG. 1. It is conveyed to (8) and injected into the some injection point 6,6 ... 6 in the ground 1.

4 is a cross-sectional view showing a specific embodiment of the unit pump 3 according to the present invention using the flanger pump 11, as shown in Figure 3, the flanger pump 11 is grounded portion of the flanger (12) A reciprocating motion is freely embedded in the cylinder 18 filled with the packing 17, and is connected to the crank 16 which rotates with the rotation of the rotation shaft 15 through the connecting rod 19. The cylinder 18 is connected to the suction hose 21 and the delivery hose 22 through the conduit 20 at the bottom of the flanger 12.

In Fig. 4, reference numeral 35 denotes a suction tank on the suction side and is covered with a cap 37. Numeral 37 is a liquid retention tank on the delivery side and is covered with a cap 38 as described above. Reference numeral 39 is a pressing piece of the caps 36 and 38.

On the basis of the operation of the flanger pump 11, as shown in FIG. 3, the direction in which the crank 16 rotates to apply the flanger 12 with the rotation of the rotation shaft 15, that is, Push upwards. At this time, the ground improving material in the ground improving material storage tank 2 shown in FIG. 1 is sucked through the suction hose 21 of FIG. 3, and the ball valve 23 is pushed to open to the movement amount of the flanger 12. Only a considerable amount is attracted and held in the holding tank 35. Then, the crank 16 rotates with the rotation of the rotation shaft 15 to lower the flanger 12 in the recovery direction, that is, downward. At this time, the ground improving material in the retained holding tank 35 is pressurized to close the ball valve 23 and push the ball valve 24 to open, and then deliver it through the conduits 20a and 20b and then the holding tank 37. It is sent to the hose 22, it is pumped to the injection pipe 8 through the conduit 10 of FIG. 1, and is injected into the some injection point 6,6 ... 6 in the ground 1. As shown in FIG.

5 is a cross-sectional view of the diaphragm pump used in the present invention, wherein the wobble plate 50 rotates with the rotation of the shaft 49 attached eccentrically to the shaft 49, and one end of the plate surface of the wobble plate 50. An inlet for the piston 53 which is in contact with the 50a and is operated by the repulsive force of the spring 52 having the diaphragm 51 at the other end, and the ground improving material formed on the diaphragm 51 side of the piston 53. And a space 56 having a 54 and an outlet 55.

The diaphragm pump configured as described above is simple and compact in structure, and the wobble plate 50 also rotates by rotating the shaft 49 during operation. Since the wobble plate 50 is eccentrically attached to the shaft 49, the plate surface 50a rotates at an angle. The piston 53 whose one end contacts the plate surface 50a swings left and right by the elastic force of the spring 52 along the direction of the plate surface 50a. At this time, the diaphragm 51 located at the other end of the piston 53 is also squeezed and oscillated, and the ground improvement material introduced through the valve 57 from the inlet port 54 by this oscillation force is the valve 58. Discharge through the discharge port 55, the introduction, discharge is repeated. In addition, the valves 57 and 58 are all check valves.

6 is an explanatory view of the squeeze pump used in the present invention, the pumping tube 41 is built in the inner surface of the drum (40). In the inner pumping chamber 44 of the pumping tube 41, a rotor 43 having pumping rollers 42 at both ends thereof is disposed so as to be freely rotatable about the rotation shaft 45.

Then, at the time of operation, the ground improving material is transported and introduced from the inlet 46 of the pumping tube 41 in the direction of the arrow, and the rotor 43 is rotated by the rotation of the rotation shaft 45 from the state of FIG. Rotate At this time, as shown in Figure 6 (b), the pumping rollers 42 and 42 at both ends of the rotor 43, while pressing the pumping tube 41 as shown in the toothpaste tube 6 (c) and 6 (d) As shown in Fig. 6), the ground improving material is pushed out to the discharge port 47 and discharged in the direction of the arrow. The pumping tube, which lacks the modifier, returns to its original state due to the restoring force of the rubber itself. The suction force reached at this time may be a vacuum degree of 740 mmHg, and the maximum discharge pressure may be 30 kgf / cm 2. This type of squeeze pump can pump high viscosity, high concentrations, solids containing solids and U-mud-like needles.

Fig. 7 is an explanatory diagram of a snake pump used in the present invention, wherein a stator 59 having a screw inside the two strands and a rotational arrangement are arranged freely in contact with the inner surface of the stator 59. A rotor 60 having a single screw thread having a pitch, a housing 61 accommodating these stators 59 and the rotor 60, and a ground 66 between a gap between the stator 59 and the rotor 60. It is comprised with the injection port 62 which introduces an improvement material from the one end 63 of the housing 61, and the discharge port 65 which discharges this ground improvement material from the other end 64 of the housing 61. As shown in FIG.

That is, the pump of FIG. 7 is basically comprised from the stator (stator) 59 fixed to the housing 61, and the rotor-shaped rotor (rotor) 60 of a neck shape. In the stator 50, the semicircular end grooves are cut into a double female screw shape at both ends, and the inner side of the rotor 60 rotates around the center of the stator 59 while maintaining the eccentric distance e mm. . However, since the stepped groove forms a wall in the stator 59, it changes to the vertical motion at the 0 ° point and to the left and right motion at the 90 ° point of the stator 59. That is, when the rotor 60 is turned in front and rotated two times in the left projection direction, the ground improving material advances the gap 66 in the stator 59 and is introduced into the injection pipe (not shown) through the conduit 10.

The relationship between the stator 59 and the rotor 6 effectively blocks the flow from the inlet to the outlet (outlet 65) at any rotational position in each stage, and the continuous action is smoothly performed. In this way, since the screw surface is completely engaged, when the rotor 60 rotates, there is no pulsation as if the piston slowly pushes the inside of the infinite cylinder in one direction, and the liquid amount is equally equal to any cross section of the stator 59. The discharge amount is always constant according to the rotational speed. In other words, the advantages of the Snake Pump are: (1) continuous compression structure, no pulsation while quiet, (2) constant capacity discharge according to the rotation speed, (3) no valve mechanism, high viscosity, high concentration of ground improvement Even if air bubbles are mixed in the ash, it can be transported. (4) It is possible to interlock with the automatic control device because the forward operation, the stop operation and the reverse operation are possible instantaneously. (5) The replacement of the stator 59 and the rotor 60 It's simple.

The unit pumps as described above usually have 5 to 100 sets as one set to constitute a multi-injection injection device, and these unit pumps are arranged horizontally, vertically, or three-dimensionally in one set. Each of these units operates as a driving source such as a motor. Each drive source is operated by a speed transmission such as an inverter controlled by a centralized management device. Therefore, the multi-injection device in one plant needs to be supported by, or integrated with, a plurality of independent unit pumps supported on a support such as a pedestal, a frame, or the like so as to prevent rocking, deformation or bending caused by the operation of each driving source.

In the present invention, the unit pumps 3, for example, 30 cm x 30 cm x 0.2 cm, are arranged or integrated by supporting a support such as four in the transverse direction, four in the longitudinal direction, three in the height direction, and a frame. In this case, the 48 unit pumps can be a multi-extension injection device 5 having a minimum volume of 1.2mx 1.2mx 0.9m. Therefore, the multi-expansion device of the present invention can be synthesized as a single, compact, integrated set of injection devices having a small capacity as a whole, consisting of 48 unit pumps. For this reason, one set of the multi-extension device uses a flanger pump as the unit pump, and the discharge pressure is 4-7 MPa at 50 Hz, the discharge amount is 1-7 liters / minute at 50 Hz, and the volume is 30 cm x 30 cm x 20. It is small in cm. Then, one unit pump is a dozen, while maintaining the optimum injection speed and injection pressure at a predetermined injection point by the inverter in the instruction from the centralized control room with the discharge amount (1-7 liter / min) from the exposure port 7 The entire injection from the discharge port (e.g., 50 discharge ports) is controlled in a range of (1 to 7) x 50 = 50 to 350 liters / minute by the centralized management room, and the interparticles are produced by low pressure and low discharge amount. It is possible to penetrate and further shorten the air by rapid construction.

Fig. 8 is a flow sheet of the apparatus of the present invention using the unit pumps 3, 3... 3 holding the A liquid suction and drain portions 3a and B liquid suction and drain portions 3b.

In FIG. 8, the A liquid tank 2a and the B liquid tank 2b are used as the ground improvement material storage tank 2, and as the unit pump 3, the conduit 9 is attached to the A liquid tank 2a. It is the same as FIG. 1 except that the unit pump 3 which has A liquid suction-exhaust part 3A which connects through this, and B liquid suction-exit part 3b which connects via the conduit 9 to the B liquid tank 2b is connected. . The unit pump 3 has a common driving source for each of the A liquid and the B liquid such that the A and B liquids from the A liquid suction and drain portion 3a and the B liquid and suction portion 3b are at a constant ratio and at a predetermined flow rate. 4) and the rotation speed transmission 25 operate.

By using the apparatus of the present invention described above, in the case of multi-point injection of the ground improvement material through the discharge port 7 of the injection pipe 8 from the plurality of injection points 6, 6. A liquid from (2a) and B liquid from tank (2b) are separately injected through respective unit pumps (3, 3, 3) of multi-injection device (5). ) Are joined to each other, and the liquid is injected at the same time into a plurality of injection points 6, 6.

9 and 10 respectively show a flow sheet of another embodiment of the apparatus according to the present invention, which basically includes a ground improvement material storage tank 2, a multi-extension injection device 5, and a plurality of injection pipes 8, respectively. The ground improvement material storage tank 2 is composed of the A liquid tank 2a and the B liquid tank 2b, and each of the A liquid and B liquid in these tanks is separately delivered to the injection pipe 8 and joined. It is. That is, in FIG. 9, after the A liquid and the B liquid are joined in the conduit 10, the condensed liquid is fed into the injection pipe 8 and injected from the discharge port 7 into the injection point 6. Two injection pipes 8 and 8 are arranged at the injection point 6 of the ground 1, and the A liquid and the B liquid are fed to the two injection pipes 8 and 8, respectively, and the discharge port 7 The injection point 6 is injected into the injection point 6, and the two are different in that they are joined in the ground 1 and reacted, or other types of improved materials are injected simultaneously or with a time difference. In this case, the two injection pipes 8 and 8 are respectively installed at separate injection points 7 spaced apart from each other, and the A liquid and the B liquid are injected into the ground 1 from the respective discharge ports 7. The liquid and the B liquid may be joined in the ground and allowed to react.

The multi-injection device 5 includes a plurality of independent unit pumps 3, 3. 3 in one plant, and each of these unit pumps 3, 3. 3 is an independent drive source 4 such as a motor. In addition, it is operated together as a set injection device by one central management device 26, and is connected to the A liquid tank 2a and the B liquid tank 2b via conduits 9, 9, 9, respectively. . These unit pumps 3, 3... 3 are multiplied in a row in a row as shown in FIGS. 9 and 10, but may be arranged in a column not shown. That is, as a specific example of these unit pumps 3, 3, 3, the flanger pump 11 shown in FIG. 3 and FIG. 4, the diaphragm pump of FIG. 5, the squeeze pump of FIG. 6, the stack pump of FIG. This is used.

The injection pipe 8 has a discharge port 7 at its tip, and is embedded in a plurality of injection points 6, 6... 6 in the ground 1 and connected to the A liquid tank 2a via a unit pump 3. , 3... 3, and unit pumps 3, 3.

In addition, the plurality of independent unit pumps 3, 3... 3 as described above are provided with rotation speed transmissions 25, 25. These rotation speed transmissions 25, 25... 25 are respectively connected to the centralized management device 26 (indicated by broken lines in the drawing) and controlled. As a result, the ground improving materials A and B liquids in the A liquid tank 2a and the B liquid tank 2b are joined at an arbitrary injection speed by the operation of the respective unit pumps 3, 3. 10 are pressed into each injection pipe 8, 8... 8, and multi-point injection into the ground 1 from each discharge port 7, 7. In addition, this multi-point injection may inject | pour and install the discharge port 7 in a planar direction as shown to FIG. 9 and FIG. 10, and as shown in FIG. 12, FIG. You may install and inject in this other position.

In addition, as shown in Figs. 9 and 10, the injection pipes 8, 8 ... 8, for example, from the unit pumps 3, 3 ... 3 to the injection pipes 8, 8 ... 8, Flow rate pressure detectors 27 are provided in the conduits 10, 10. The flow rate and / or pressure data signals of the ground improving material detected from these spreaders 27 are transmitted to the centralized management device 26 as indicated by broken lines in FIGS. 9 and 10. Thus, as shown in Fig. 10, a plurality of injections from a plurality of unit pumps 3, 3... 3 independent of the ground improvement material, while collectively monitoring the injection situation with the injection monitoring panel 29 of the injection management apparatus 26. Multi-point injection is carried out at the several injection point in the ground 1 via the pipe 8.

The operation of the plurality of unit pumps 3, 3... 3 is controlled via the speed transmission 25 based on the flow rate and / or pressure data signals of the ground improving material transmitted to the centralized management device 26. Under such control, the ground improving material is maintained at a desired pressure and / or flow rate, and is fed to each injection pipe 8, 8.

Further, the flow rate and / or pressure data signal of the ground improvement material detected by the flow pressure detector 27 is transmitted to the centralized management device 26, and these data are displayed on the injection monitoring panel 29 of the injection management device 26. By displaying, the injection condition is collectively monitored to maintain the injection pressure and / or flow rate in the injection pipe 8 in a predetermined range, and the injection is completed or stopped based on the information of the data. Continue or reinject. 9 and 10, reference numeral 28 denotes a valve such as a switching valve, a stop valve, or a return valve. As shown in FIG. 10, the valve 28 is connected to the centralized management device 26 to control it. It is possible to be able to.

The injection monitoring panel 29 includes "time data" such as the injection date, date, and injection time, and the injection block No. "Injection data" such as the "place data" such as the hole number of the injection hole, the injection point, and the like, the injection pressure, the flow rate (unit time flow rate and the accumulated flow rate) are displayed. Is written on. In this way, the operation of each of the plurality of unit pumps 3, 3... 3 passing through the plurality of injection pipes 8, 8. 8 can be optimally controlled in accordance with the injection situation of each injection tube 8. In addition, the plurality of unit pumps 3, 3... 3 can be collectively managed. FIG. 11 is an example of collectively monitoring the pressure flow rate and the accumulated flow rate of each of the ten injection pipes 8, 8. In addition, in the present invention, instead of the Y magnetic pipe lot, the injection pipe 8 may be a double pipe double packer injection pipe, a single pipe, or the like. In Fig. 10, reference numeral 30 denotes a construction display board, and 31 denotes a daily work device.

12 is an explanatory view showing another specific example of the multi-point ground injection apparatus according to the present invention. First, the ground 1 is cut by a casing pipe or the like not shown to form the injection point 6. The injection point 6 is filled with a real material 32 and a plurality of injection pipes 8, 8. Each of these injection pipes 8, 8... 8 is a fine tube having a diameter of, for example, a few mm, and the discharge ports 7, 7. A plurality of bindings are performed at different positions in the axial direction, sequentially deep positions, for example, 7-1, 7-2, ... 7-i from the shallow position to the deep positions sequentially. The ground injection material of the storage tank 2 is formed by the conduit 9, the assembly of the unit pump 33, the conduit 10, and the flow pressure detector 27 of each injection pipe 8, 8. It is injected into the injection point 6 in the ground 1 from the discharge ports 7 and 7. Each unit pump in the assembly 33 of the unit pumps is controlled by an instruction from the centralized management device 26 based on the information from the flow pressure detector 27.

In filling the actual material 32, a check valve (not shown) is provided in each of the discharge ports 7, 7... Of the plurality of tubules 8, 8. Prior to injecting the ground improving material from), a real material 32 may be formed by filling a real material (hardening material) between the gap between the injection tube 8 and the ground 1. As the check valve, a rubber sleeve, a stopper, or the like is used.

In addition, the tubules may be set as two sets, and the tubule set provided with the check valve in the front-end discharge port 7 may be plural, and a plurality of tubule sets are tied so that the position of a discharge port may differ in an axial direction. By using such a customs set, the A and B liquids are respectively transferred from separate customs, and the nutrient solution is merged at the discharging end, whereby the improved material having a short gelling time can be injected. Injection of an improved material can also be performed.

In the apparatus of FIG. 12 configured in this way, the ground improving material of the storage tank 2 is connected to each injection pipe via the flow rate pressure detector 27 through the conduit 9, the assembly 33 of the unit pump, and the conduit 10. A predetermined amount is discharged simultaneously or selectively from the discharge ports 7-1, 7-2, ... 7-i of (8, 8 ... 8), and the practical mortar (real) of the injection point 6 (32) ) Is torn and injected into the bulb shape in the ground 1 of a predetermined level.

FIG. 13 shows the injection tube 8 formed by using the same multi-point ground injection apparatus A as shown in FIG. 1 (FIG. 13A), and combining a plurality of fine tubes having the same shape as that of FIG. As shown in the figure, an example in which the injection points 6 of the first injection block and the second injection block are embedded and implanted simultaneously or selectively is shown. The inlet tube 8 placed in FIG. 13 (a) has its respective capillaries (T ₁₁ , T _12... T _1i , T _1n ; T ₂₁ , T _22... T _2i , T _2n ; T _i1 , T _{i2 ...} T _i1 , T _in; -; T _n1 , T _{n2 .T ni} , T _nn ). As shown in Fig. 13 (b), the tip discharge port of T ₁₁ , T _21... T _i1 , T _ni is provided in the first stage, and T ₁₂ , T _22... T _i2 , T _n2 is provided in the second stage. of the leading end discharge port, the I stage, the T _1i, T _2i and and T _ii, the leading end discharge port of the T _ni, the n-th stage, the ground so as to be positioned respectively the leading end discharge port of the T _1n, T _2n and and T _in, T _nn We bury in (1).

In FIG. 13, the flow rate and / or pressure data of the ground improving material detected from the flow rate pressure detector 27 of the plurality of conduits 10, 10... 10 are transmitted to the centralized management device 26, and the data is recorded and recorded. Injection control is performed by collectively monitoring the injection status by the screen display.

Since the alluvial layer is generally opposed horizontally, the permeability coefficient in the horizontal direction is larger than that in the vertical direction. Therefore, in FIG. 13, the soil layer of the first stage has almost the same water permeability coefficient in the vicinity of any discharge port, for example, is heavy yarn. In addition, the soil layer of the nth stage is also a fine yarn, for example with the same permeability coefficient near any discharge port. At the time of injection, first, the first stage is injected simultaneously using n injection tubes T _{11 to} T _n1 , and then the second stage is injected from the second stage to the nth stage. In FIG. 13, after the injection of the first injection block is completed, the injection block moves to the second injection block. As shown in FIG. 11, the n injection situations of the i-th stage are collectively managed in the injection monitoring panel and controlled to perform optimal injection for each injection tube.

In addition, in the present invention, each unit pump is driven by a drive source such as an independent motor, respectively, and the integrated unit pump is operated as a set of multiple extension injection apparatuses by controlling the rotation speed transmission such as an inverter with the centralized management device. Moreover, the multiple extension injection device can arbitrarily manage the injection of each injection tube in response to the injection situation of the plurality of injection tubes. That is, the multi-extension injection device is a device having a function of optimally managing the injection of each injection pipe as well as the management of the entire injection of a plurality (n) injection pipes. In the present invention, in the injection, for example, when the discharge amount per unit is 0 to 5 liters / minute, the discharge amount per set of the multi-injection device is 0 to 5 liters xn = 0 to 5 xn liters / minute, and the number of unit pumps n = 30 5 n = 150 liters / minute.

As described above, since the multi-point ground injection method of the present invention uses a multi-extension injection device having a plurality of independent unit pumps, an optimal injection is performed simultaneously or selectively for each of these layers for the ground where the fat situation is different for each layer. It can achieve and three-dimensional injection in the longitudinal direction and the transverse direction in the ground is also possible.

In addition, the multi-point ground injection device of the present invention is a device having a multi-extension injection device, and comprising a plurality of unit pumps as described above at the same time at any amount, any discharge rate, or It is possible to selectively inject, and to inject different layers for each layer in the ground situation, optimum injection can be performed for each of these layers, and the injection air is shortened.

In addition, the present invention has a low discharge rate, for example, (1 liter or less to several liters) per minute, and a variable discharge amount of (1 to 7 liters) per minute, and infiltrate injection into the fine soil layer without causing ground breakage. It is possible to improve the reliability of the penetration injection into the fine soil layer and to shorten the air by rapid construction of 50 to 350 liters per minute.

Also, by injecting A liquid and B liquid together and changing the discharge amount of A liquid and B liquid during injection, any gel time can be performed at each discharge port, and when it deviates again, only the injection tube is stopped and many other injections are performed. Injection from the tube may continue as is. In addition, since all the injection pipes are provided in the ground, the discharge port can be selected and the secondary injection can be carried out at another discharge port. Therefore, the low pressure penetration injection can be uniformly carried out according to the design from all the injection pipes into the ground.

1 is an explanatory diagram showing a principle diagram of a device according to the present invention;

2 is a principle diagram of a piston pump,

3 is a principle diagram of using a flanger pump as a unit pump,

4 is a cross-sectional view of an embodiment using the flanger pump as the unit pump,

5 is a cross-sectional view of a diaphragm pump used in the unit pump of the present invention;

6 is a cross-sectional view of the squeeze pump used in the unit pump of the present invention, (a) to (d) is a process chart showing each operation state,

7 is a cross-sectional view of the snack pump used in the unit pump of the present invention,

8 is a flow sheet of one embodiment of the apparatus according to the invention,

9 is a flow sheet of another embodiment of an apparatus according to the invention,

10 is a flow sheet of another embodiment of an apparatus according to the invention,

11 is one specific example displayed on the injection monitoring panel of the centralized management device,

12 is a flow sheet of another embodiment of the apparatus of the present invention using a plurality of tubules as an injection tube,

13 is a flow sheet of another embodiment of an apparatus according to the invention.

<Explanation of symbols for the main parts of the drawings>

A: Multi-point ground injection device

1: Ground 2: Ground tank for storage of improved soil

2a: tank for A liquid 2b: tank for B liquid

3: unit pump

3a: A liquid suction part 3b: B liquid suction part

4: driving source 5: multi-extension injection device

6: injection point 7: discharge port

8: injection tube 9,10,20: conduit

11: flanger pump 12: puller

13: piston rod 14: crankshaft

15: rotation axis 16: crank

17: grand packing 18: cylinder

19: connecting rod 21: suction hose

22: delivery hose 23,24: ball valve

25: speed transmission 26: centralized management device

27: flow pressure detector 28: valve

29: injection monitoring panel 30: construction display panel

31: daily work device 32: real-ash

33: aggregate of unit pump 34: injection zone

35,37: Reservoir Tank 36,38: Cap

39: press piece 40: drum

41 pumping tube 42 pumping roller

43: rotor 44: pump chamber

45: rotation axis 46: inlet

47: discharge port 48: connecting portion

49: shaft 50: wobble plate

50a: plate surface 51: diaphragm

52: spring 53: piston

54: inlet port 55: outlet port

56: space 57,58: valve

59: stator 60: rotor

61 housing 62 injection hole

63: first 64: the other end

65: outlet 66: gap

67: Inverter 68: Piston Pump

Claims (14)

As a ground injection method in which a plurality of injection pipes having discharge ports are embedded at a plurality of injection points in the ground, and multiple point injections of ground improvement materials are simultaneously carried out from the plurality of discharge holes through these injection pipes. A multi-extension injection device having a plurality of unit pumps, each unit pump being operated by an independent driving source, is used, and the plurality of unit pumps are connected to the plurality of injection pipes through conduits, and the plurality of unit pumps. The ground improvement material is injected from the plurality of discharge ports through a plurality of injection points in the ground by the operation of the plurality of unit pumps, the plurality of unit pumps are controlled by the centralized management device, the centralized management device is a flow rate and / or pressure data The multi-point ground injection method, characterized in that the multi-point injection of the ground improving material to the plurality of injection points in the ground through the unit pump. delete The method of claim 1, Multi-point ground injection method, characterized in that the discharge port of the plurality of injection pipes are provided at injection points of different plane direction. The method of claim 1, Multi-point ground injection method, characterized in that the discharge port of the plurality of injection pipe is provided at the injection point of the depth direction is different. The method of claim 1, A flow pressure detector is installed in the conduit leading to the plurality of injection pipes, and a signal of the flow rate and / or pressure data of the ground improvement material detected by these detectors is transmitted to the centralized management device, and the ground improvement material is based on the information. A multi-point ground injection method, characterized in that the multi-point injection into the plurality of injection points in the ground through the discharge port of the plurality of injection pipes from each unit pump. The method of claim 5, The unit pump has a rotation speed transmission controlled by a centralized management device having an injection monitoring panel, respectively, and operates the rotation speed transmission based on a data signal detected from the flow pressure detector, and the pressure and / or Multi-point ground injection method characterized in that the liquid is maintained at a flow rate and fed to each injection pipe. The method of claim 5, The flow rate and / or pressure data signal of the ground improvement material detected by the flow pressure detector is displayed on the injection monitoring panel to collectively monitor the injection situation, and the respective injection pressures and / or flow rates in the injection pipes are in a predetermined range. And the injection is completed, stopped, continued or re-injected based on the data information. A multi-extension injection device connected to the storage tank having a ground improvement material storage tank and a plurality of unit pumps operated as independent driving sources in one plant and controlled by a centralized management device, and a plurality of injection points of the ground. And a plurality of injection pipes each having a discharge port embedded therein and connected to each of the unit pumps through a conduit, and in the plurality of independent unit pumps, a rotation speed transmission controlled by a centralized management device, respectively, again The conduit is provided with a flow pressure detector, which transmits a signal of flow rate and / or pressure data from the flow pressure detector to the centralized management device, and transmits the ground improving material in the tank to the operation of each unit pump. To the respective injection tubes at an arbitrary injection speed, injection pressure or injection volume, and multi-point injection into the ground simultaneously from a plurality of discharge ports. Ground multipoint injection device, characterized in that. The method of claim 8, The unit pump is a multi-point ground injection device, characterized in that any one of a flanger pump, a diaphragm pump, a squeeze pump, a neck pump. The method of claim 8, The multi-extension injection device is a multi-point ground injection device, characterized in that arranged in a row, column, or three-dimensional array of a plurality of five or more unit pumps. The method of claim 10, A plurality of unit pumps are arranged to be supported by a support, or are arranged integrally, multi-point ground injection device characterized in that to prevent the fluctuation, deformation or bending by a plurality of drive sources. The method of claim 8, Signals of the flow rate and / or pressure data of the ground improvement material detected by the flow pressure detector are transmitted to the centralized management device, and the injection condition is collectively monitored by the injection monitoring panel of the injection management device, and the ground improvement material is collected from a plurality of independent unit pumps. A multi-point ground injection apparatus, characterized in that the multi-point injection into a plurality of injection points in the ground through a plurality of injection pipes. The method of claim 8, The rotation speed transmission is controlled based on the flow rate and / or pressure data signal of the ground improver transmitted to the centralized management device, whereby the ground improver is characterized in that to deliver the desired pressure and / or flow rate to each injection pipe Multi-point ground injection device. The method of claim 8, Signals of the flow rate and / or pressure data of the ground improvement material detected by the flow rate pressure detector are transmitted to the centralized management device, and these data are displayed on the injection monitoring panel of the injection management device to collectively monitor the injection situation. Injecting while maintaining the respective injection pressure and / or flow rate in a predetermined range, and complete, stop, continue or re-injection on the basis of the information of the data, characterized in that the multi-point ground injection device.