JP6823776B2 - Mobile mud dehydrator and mud dehydration method - Google Patents

Description

The present invention relates to a mobile mud dehydrator and a method for dehydrating mud using the mobile mud dehydrator.

Patent Document 1 proposes a ground improvement method.
In this construction method, saturated groundwater is pumped by negative pressure propagation using SWP (super well point), so that the water level can be expected to drop in spots mainly in the target area and an unsaturated zone is created. After that, using SWP's vacuum pump or vortex pump, vacuum vaporization is promoted in the unsaturated zone to remove water, VOCs (volatile organic compounds), oil and other vaporizable substances from the ground. Then, promote ground improvement and soil purification.
The basis of this ground improvement method is a method in which groundwater is forcibly drained by vacuum suction to form an unsaturated zone to promote vacuum vaporization and promote dehydration and drying.

Japanese Patent No. 4114944 (Japanese Unexamined Patent Publication No. 2007-303095)

By the way, when sludge and mud were sucked with a small SWP, sludge stuck around the screen in a consolidated state in a dumpling state, and gravity water and the like on the back surface could not be sucked.
In natural ground, even if negative pressure suction is performed after cleaning, it will not be clogged, but if artificial mud with a high water content ratio (e ≈ 100 to 1000%) is vacuum-sucked, colloidal particles will be generated. It moved and stuck around the screen, causing clogging.

An object of the present invention is to provide a mud dehydrator that can move in response to clogging.

In order to solve the above problems, the invention according to claim 1 is
A movable mobile device equipped with a movable member and
A muddy water suction pipe attached to the movable member,
A muddy water suction pump that is connected to the muddy water suction pipe and is inserted into the muddy soil to suck muddy water from the muddy water suction pipe, and a vacuum pump that vacuum sucks air.
It features a mobile mud dehydrator equipped with.

The invention according to claim 2
The mobile mud dehydrator according to claim 1.
The muddy water suction pipe is characterized in that a portion inserted into the muddy soil has a water permeation hole, a separate screen covering the periphery thereof is provided, and a press-fitting cone for being press-fitted into the muddy soil is provided at the tip thereof.

The invention according to claim 3
The mobile mud dehydrator according to claim 1.
A compressor that supplies pressure is connected to the muddy water suction pipe.

The invention according to claim 4
The mobile mud dehydrator according to claim 1.
The moving machine is a backhoe provided with a bucket as the movable member, and is characterized in that the muddy water suction pipe is fixed to the bucket.

The invention according to claim 5
The mobile mud dehydrator according to claim 1.
A high-frequency vibro is attached to the muddy water suction pipe.

The invention according to claim 6
Using the mobile mud dehydrator according to claim 1, the muddy water suction pump is used to suck muddy water from the muddy water suction pipe inserted into the muddy soil by the movable member, and the vacuum pump is used to vacuum suck air. It is characterized by a mud dehydration method in which the process is repeated every time the moving machine is moved.

The invention according to claim 7
A method for consolidating mud is characterized by using the mobile mud dehydrator according to claim 2 to press-fit the mud suction pipe into the mud with the press-fitting cone at the tip.

The invention according to claim 8 is
Using the mobile mud dehydrator according to claim 3, the muddy water suction pipe was pulled up from the mud by the movable member, and pressure was supplied to the muddy water suction pipe by the compressor to adhere to the separate screen. It features a mud dehydration method that blows away mud.

The invention according to claim 9
Using the mobile muddy soil dehydrator according to claim 5, the muddy water suction pipe is pulled up from the muddy soil by the movable member, and the muddy water suction pipe is vibrated at high frequency by the high frequency vibro, and the separate screen is clogged. It is characterized by a mud dewatering method in which the soil particles are vacuum-sucked by the vacuum pump.

According to the present invention, clogging can be easily dealt with by moving the device to dehydrate the mud.

It shows the structure of one Embodiment of the mobile mud dewatering apparatus to which this invention was applied, and is the side view of the main part breaking which showed the outline of the mud dewatering work. It is an enlarged view of the muddy water suction pipe part of FIG. It is a top view which shows the dehydrated soil pit of another facility. It is a vertical sectional view of the dehydrated soil pit of FIG. It is a schematic plan view which shows the case of the mud carrier of Embodiment 2. It is a vertical cross-sectional view of a main part of a modification. It is a schematic side view which shows the case of the residual soil treatment facility of Embodiment 3. It is a schematic plan view which shows the case of the dredging soil treatment system of Embodiment 4. It is a side view of the main part fracture of FIG.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.
(Embodiment 1)
FIG. 1 shows a configuration of an embodiment of a mobile mud dehydrator to which the present invention is applied, in which 1 is a mud pit, 2 is a back ho (moving machine), 3 is a muddy water suction pipe, 4 is a suction hose, and 5 is. A switching valve, 6 is a suction hose, 7 is a pressure air supply hose, 11 is a muddy water suction pump, 12 is a vacuum pump, 13 is a suction hose, 14 is a compressor, and 15 is a generator.

As shown in the figure, mud is stored in the mud pit 1, and the mud suction pipe 3 attached to the bucket 2a, which is a movable member of the backhoe 2 which is one of the moving machines moving on the ground, is the mud pit 1. It is press-fitted into the mud and inserted.

The muddy water suction pipe 3 has a diameter of about 100 mm, and as shown in an enlarged view in FIG. 2, a large number of water permeation holes 3a are formed on the tip side of the muddy water suction pipe 3, and the periphery thereof is a separate screen 3b with a filter. It is covered, and the periphery thereof is covered with a punching metal tube 3c having a diameter of about 110 mm as a protective tube.

Further, the tip of the muddy water suction pipe 3 has a shape cut diagonally, and a press-fitting cone 3d that closes the open end of the muddy water suction pipe 3 and guides press-fitting is attached.
The above muddy water suction pipe 3 is fixed to the tip of the bucket 2a of the backhoe 2 with a fixing band 3e.

Further, a switching valve 5 is connected to the suction hose 4 connected to the muddy water suction pipe 3 on the ground side. A muddy water suction pump 11 on the ground is connected to a suction hose 6 connected to the switching valve 5. A suction hose 13 connected to the ground vacuum pump 12 is connected to the muddy water suction pump 11.
As described above, the muddy water suction pipe 3 has the same configuration as the small SWP.

Further, a compressor 14 mounted on a vehicle on the ground is connected to a pressure air supply hose 7 connected to the switching valve 5.
The muddy water suction pump 11 and the vacuum pump 12 are electrically connected to the generator 15 installed on the ground.

As shown in FIG. 1, the mobile mud dehydrator having such a configuration press-fits the mud suction pipe 3 into the mud in the mud pit 1 with the press-fitting cone 3d by the bucket 2a. As a result, the mud under the press-fitting cone 3d is consolidated by pressurization.
Then, as shown in FIG. 2, the water in the mud is squeezed out and separated into the compacted soil and the floating water by the dense pressure of the mud by the press-fitting cone 3d.

Subsequently, the step of sucking muddy water from the muddy water suction pipe 3 press-fitted into the muddy soil by the muddy water suction pump 11 and vacuum sucking air by the vacuum pump 12 is repeated every time the back hoe 2 is moved.

Here, in the muddy water suction pipe 3, the floating water in the muddy soil is sucked through the small holes of the punching metal tube 3c, the separate screen 3b, and the water permeation hole 3a by the suction of the muddy water suction pump 11, and the suction hose 4 It is sucked into the muddy water suction pump 11 through the switching valve 5 and the suction hose 6 and drained.
Further, the air in the muddy water suction pipe 3 is vacuum-sucked and exhausted by the vacuum pump 12, so that the water in the muddy water flows into the muddy water suction pipe 3.

In the above, when the separate screen 3b is clogged, the muddy water suction pipe 3 is pulled up, the sticking scale is removed in the muddy soil pit (see FIGS. 3 and 4), and the switching valve 5 is switched as shown in FIG. The pressure of the compressor 14 reversely injects the separate screen 3b to recover the clogging.
The mesh size is changed depending on the soil conditions.

In this way, by attaching the muddy water suction pipe 3 to the bucket 2a of the back hoe 2, the muddy water suction pipe 3 can be press-fitted into the muddy soil, and the muddy soil is partially consolidated to minimize the movement of colloidal components and float. Water and slag can be sucked in spots to improve suction efficiency.
Moreover, since the muddy water suction pipe 3 with the separate screen 3b can be easily moved, first sucks only the wrinkled water, then sucks the loose part, and removes the slag attached to the separate screen 3b each time it moves. The entire water content can be removed and dehydrated.
Then, by press-fitting the muddy water suction pipe 3 with the press-fitting cone 3d, it is possible to aim for, for example, a cone index of 200th, leaving only the core of the cohesive soil.

As described above, according to the mobile mud dehydrator of the embodiment, since the mud suction pipe 3 connected to the mud suction pump 11 and the vacuum pump 12 is attached to the bucket 2a of the backhoe 2, the backhoe 2 is moved to move the backhoe 2 to the mud pit 1. By dehydrating the mud inside, clogging can be easily dealt with.

3 and 4 show the dehydrated soil pit 21 of another facility, and as shown in the drawing, scale stripping plates 22 are provided on both opposite sides in the dehydrated soil pit 21, and the scale stripping plate 22 is provided. A semicircular notch-shaped stripping portion 23 is formed in the center.

First, the muddy water suction pipe 3 attached to the bucket 2a of the backhoe 2 is placed in the dehydrated soil pit 21 and horizontally moved to peel off the punching metal pipe 3c outside the muddy water suction pipe 3 in a semicircular shape on the scale stripping plate 22. Apply to part 23.
Then, the muddy water suction pipe 3 is moved up and down, and while being sucked by the muddy water suction pump 11, the slag sticking to the outside of the punching metal pipe 3c is peeled off by the semicircular stripping portion 23, and the inside of the dehydrated soil pit 21. Can be scraped off.

(Embodiment 2)
FIG. 5 shows the case of the mud carrier of the second embodiment. Similar to the first embodiment, 3 is a muddy water suction pipe, 4 is a suction hose, 11 is a muddy water suction pump, 12 is a vacuum pump, and 13 is a suction hose. , 14 is a compressor, 15 is a generator, 21 is a dehydrated soil pitch, 22 is a scale stripping plate, 23 is a stripping part, 31 is a towboat, 32 is a towline, 33 is a pontoon, 34 is mud. A tank, 35 is a muddy water tank, 36 is a cooling water tank, 41 is a rail, 42 is a dehydration robot (mobile device), 43 is an arm, 44 is a hydraulic unit, and 45 is a control panel.

As shown in the figure, the pontoon 33 towed by the towboat 31 by the towline 32 is provided with a dehydrated soil pitch 21, a mud tank 34, a muddy water tank 35, and a cooling water tank 36, and one side of the mud tank 34. A pair of rails 41 are laid along the railroad. A dehydration robot 42, which is a moving machine that moves horizontally along the rail 41, is mounted, and a muddy water suction pipe 3 is attached to an arm 43 of the dehydration robot 42.
Further, the pontoon 33 is provided with a muddy water suction pump 11, a vacuum pump 12, a compressor 14, a generator 15, a hydraulic unit 44, and a control panel 45.

In such a mud carrier, a mud suction pipe 3 is attached to an arm 43 of a dehydration robot 42 that horizontally moves along a rail 41 on a pontoon 33 provided with a dehydrated soil pitch 21, a mud tank 34, a mud tank 35, and a cooling water tank 36. Is attached, and the mud dehydration work is performed on the control board 45 as described above.

As described above, according to the mud carrier provided with the mobile mud dehydrator of the second embodiment, the mud suction pump 11 and the vacuum pump 12 are connected to the arm 43 of the dehydration robot 42 that moves horizontally along the rail 41 on the pontoon 33. Since the muddy water suction pipe 3 is attached, the dewatering robot 42 can be horizontally moved along the rail 41 on the pontoon 33 to dewater the muddy soil in the muddy soil tank 34, whereby clogging can be easily dealt with. ..

(Modification example)
FIG. 6 shows a modified example. Similar to the first embodiment, 3 is a muddy water suction pipe, 3a is a water permeation hole, 3b is a separate screen, 51 is a high frequency vibro, and 52 is a band.

As shown in the figure, a high frequency vibro 51 is attached to the muddy water suction pipe 3 with a band 52.
Here, in order to prevent clogging of the separate screen 3b, the mesh mesh is enlarged (coarse) from about 1 mm to about 3 mm and sucked.

First, when the muddy water suction pipe 3 is inserted into the muddy soil, the muddy water suction pipe 3 is sucked by the muddy water suction pump 11 and the vacuum pump 12 is used for vacuum suction, the top water is sucked as shown in the figure. It can be removed, and the next loose cohesive soil can also be removed by suction.
Subsequently, as for the bottom hard cohesive soil, the insertion of the tip of the muddy water suction pipe 3 is stopped by the hard cohesive soil, and air enters the permeable hole 3a and cannot be sucked. Therefore, the hard cohesive soil is left as a core. be able to.

Then, the muddy water suction pipe 3 was vibrated at high frequency by the drive of the high frequency vibro 51, and the muddy water suction pipe 3 was sucked by the muddy water suction pump 11 and vacuum sucked by the vacuum pump 12, so that the separate screen 3b was attached in a sludge shape. The particles can be sucked to prevent the occurrence of clogging.

(Embodiment 3)
FIG. 7 shows the case of the residual soil treatment equipment of the third embodiment. Similar to the first embodiment, 2 is a backhoe, 3 is a muddy water suction pipe, 3b is a separate screen, 4 is a suction hose, and 11 is a muddy water suction pump. 61 is a residual soil pit, 62 is a sand master (vibration sieve), 63 is a muddy water tank, and 64 is a dump truck.

As shown in the figure, the tip of the muddy water suction pipe 3 attached to the arm 2b of the backhoe 2 by the attachment 2c is inserted into the residual soil in the residual soil pit 61.
Further, a sand master 62, which is a vibration sieve, is provided below the muddy water suction pipe 11. The sand master 62 is arranged on a muddy water tank 63 installed on the ground.

As described above, according to the residual soil treatment facility provided with the mobile mud dehydrator of the third embodiment, the muddy water suction pipe 3 having the tip inserted into the residual soil in the residual soil pit 61 is sucked by the muddy water suction pump 11 and sucked and sanded. Collect the sludge grains sifted by the master 62.
Then, the collected sludge grains are loaded on a dump truck 64 and transported to a water treatment plant of another facility.

(Embodiment 4)
8 and 9 show the case of the dredging soil treatment system of the fourth embodiment, and as in the first embodiment, 2 is a back pump, 2a is a bucket, 3 is a muddy water suction pipe, 4 is a suction hose, and 11 is. Muddy water suction pump, 12 is a vacuum pump, 13 is a suction hose, 14 is a compressor, 15 is a generator, 71 is a grab ship, 72 is a dredging crane, 73 is a soil carrier, 74 is a dredging soil tank, 75 is dehydration. A work ship, 76 is a cooling water tank, and 77 is a muddy water protection sheet.

As shown in the figure, the dehydration work vessel 75 is loaded with a backhoe 2 provided with a muddy water suction pipe 3 in a bucket 2a, and a muddy water suction pump 11, a vacuum pump 12, a compressor 14, a generator 15, and a cooling water tank 76 are installed. ing.

As described above, according to the dredging soil treatment system provided with the mobile mud dewatering device of the fourth embodiment, the dredging soil charged into the dredging soil tank 74 of the soil carrier 73 by the dredging crane 72 of the grab ship 71 is applied to the dehydration work ship 75. By inserting the tip of the muddy water suction pipe 3 provided in the bucket 2a of the loaded back hoe 2, sucking the muddy water suction pipe 3 with the muddy water suction pump 11 and vacuum sucking with the vacuum pump 12, the dredged soil tank of the soil carrier 73 By dehydrating the mud in 74, clogging can be easily dealt with.

(Other variants)
In the above embodiments, the mobile device is a backhoe or a robot, but the present invention is not limited to this, and other vehicles or heavy machines may be used.
In addition, it goes without saying that the specific detailed structure and method can be changed as appropriate.

The present invention is used to deal with clogging due to mud suction, and can be used as a device for moving and dehydrating mud.

1 Mud pit 2 Backhoe (mobile machine)
2a bucket (movable member)
3 Muddy water suction pipe 3a Water permeation hole 3b Separate screen 3c Punching metal pipe (protective pipe)
3d Press-fit cone 3e Fixed band 4 Suction hose 5 Switching valve 6 Suction hose 7 Pressure air supply hose 11 Muddy water suction pump 12 Vacuum pump 13 Suction hose 14 Compressor 15 Generator 21 Dehydrated soil pit 22 Scale stripping plate 23 Stripping part 31 Pulling ship 32 Tow rope 33 Pump 34 Mud soil tank 35 Mud water tank 36 Cooling water tank 41 Rail 42 Dehydration robot (mobile machine)
43 Arm 44 Hydraulic unit 45 Control board 51 High frequency vibro 52 Band 61 Remaining soil pit 62 Sand master (vibration sieve)
63 Muddy water tank 64 Dump truck 71 Grab ship 72 Dredging crane 73 Soil carrier 74 Dredging soil tank 75 Dehydration work ship 76 Cooling water tank 77 Muddy water protection sheet

Claims (6)

A movable mobile device equipped with a movable member and
A muddy water suction pipe attached to the movable member,
A muddy water suction pump that is connected to the muddy water suction pipe and is inserted into the muddy soil to suck muddy water from the muddy water suction pipe, and a vacuum pump that vacuum sucks air.
It is a mobile mud dehydrator equipped with
The muddy water suction pipe has a water permeation hole at a portion to be inserted into the mud, a separate screen covering the periphery thereof is provided, and the tip is cut diagonally, and the shape is cut diagonally. A press-fitting cone is attached to block the open end of the pipe and guide the press-fitting into the mud.
The mobile machine is a backhoe including a bucket as the movable member, and is a mobile mud dehydrator in which the muddy water suction pipe is fixed to the bucket by a fixing band. The mobile mud dehydrator according to claim 1, wherein a compressor for supplying pressure air is connected to the muddy water suction pipe. The mobile mud dehydrator according to claim 1, wherein a high-frequency vibro is attached to the muddy water suction pipe. A step of sucking muddy water by the muddy water suction pump and vacuum sucking air by the vacuum pump from the muddy water suction pipe inserted into the muddy soil by the bucket using the mobile muddy soil dehydrator according to claim 1. Is a mud dehydration method that is repeatedly performed every time the back pump is moved.
A method for dewatering mud, which comprises compacting the mud by press-fitting the mud suction pipe fixed to the bucket of the backhoe with the fixing band by the press-fitting cone at the tip. Using the mobile mud dehydrator according to claim 3, the mud suction pipe is pulled up from the mud by the bucket, and pressure is supplied to the mud suction pipe by the compressor, so that the mud adhered to the separate screen. A method of dehydrating mud, which is characterized by blowing off. Using the mobile muddy soil dehydrator according to claim 5, the muddy water suction pipe was pulled up from the muddy soil by the bucket, and the muddy water suction pipe was vibrated at high frequency by the high frequency vibro, and the separate screen was clogged. A method for dehydrating soil, which comprises vacuum-sucking soil particles with the vacuum pump.

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