JP6850052B1 - Dredging device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently excavate and remove sediments while suppressing the influence on the environment even if obstacles such as sunken trees are mixed in the sediments deposited in rivers, harbors, dams, lakes and marshes. Provide a dredging device. SOLUTION: The dredging device 1 is a dredging device 1 for dredging sediment accumulated on the bottom of a water while descending in water due to a mixture of obstacles such as sunken trees, and is a casing 10 and the inside of the casing 10. Has a submersible pump 11 for sucking and discharging the accumulated sediment and a tip portion 13a provided with an opening 13b, which is formed thinner than the casing 10 and at least extends downward from the casing 10. The suction pipe 13 of 1 is provided, and the tip portion 13a sucks the sediment from the opening 13b while entering between the obstacles and pushing away the obstacles. [Selection diagram] Fig. 2

Description

The present invention relates to a dredging device used for dredging sediments deposited in rivers, harbors, dams, lakes and marshes.

Conventionally, a submersible sand pump that is stored and fixed in a cylindrical casing with a top plate with an open lower end surface, and a plurality of high-pressure waters that penetrate the top plate and are arranged in the vertical direction along the inner peripheral wall surface of the casing. It is equipped with an injection nozzle provided at the pipe and its tip, and a stirring blade fixedly installed at a position near the lower center of the casing on the lower surface side of the submersible sand pump, and high-pressure water is injected from the injection nozzle to deposit sediment. There is known a dredging device in which the sediment is crushed into small pieces and agitated by a stirring blade to raise the accumulated sediment and sucked and discharged by a submersible sand pump. According to such a dredging device, it is said that efficient excavation and removal of sediment can be performed without adversely affecting the environment. (Refer to Patent Document 1) In addition, the sediment containing a mixture of bark and sunken trees in the dredging area is grabbed by the bucket of a lifting heavy machine and dredged, and the sediment containing this mixture is put into the sorting water tank of the sorting device. However, a dredging method for separating the mixture and the sediment is known. According to such a dredging method, it is said that sediment and mixed matter can be easily separated, the work capacity does not change much depending on the soil quality, and the separation work can be performed efficiently. (See Patent Document 2)

However, in the above-mentioned prior art, there are points to be improved as described below.

That is, in the dredging device of Patent Document 1, when obstacles (for example, sunken trees) are mixed in the sediment, the obstacles prevent the lower end surface of the casing from descending, so that the excavation / removal work of the sediment is efficient. There was a problem that I couldn't do it well. Further, in the dredging method of Patent Document 2, there is a problem that when the sediment containing obstacles in the dredging region is grasped and moved, the sediment makes the water turbid and adversely affects the environment.

Japanese Unexamined Patent Publication No. 2010-031623 Japanese Unexamined Patent Publication No. 2011-202501

The present invention has been devised under the above-mentioned circumstances, and even if obstacles such as sunken trees are mixed in the sediments accumulated in rivers, harbors, dams, lakes and marshes, the environment It is an object of the present invention to provide a dredging device capable of efficiently excavating and removing sediment while suppressing the influence on the river.

The dredging device provided by the present invention is a dredging device for dredging sediment accumulated on the bottom of the water while descending in water due to a mixture of obstacles such as sunken trees, and is provided in a casing and inside the casing. At least one suction pipe that has a submersible pump for sucking and discharging the accumulated sediment and a tip portion provided with an opening, is formed thinner than the casing, and extends downward from the casing. And, the tip portion enters between the obstacles and sucks the deposited sediment from the opening while pushing away the obstacles, and the dredging device has the tip portion in the at least one suction pipe. Further comprises an auxiliary device, which causes a movement to assist the entry between the obstacles and pushing away the obstacles, the auxiliary device vibrating and / or causing the at least one suction tube as the auxiliary movement. It is characterized by having a configuration that causes rotation.

Preferably, the tip portion has a shape that narrows toward the tip.

Preferably, the dredging device is further provided with a high-pressure jet water jet nozzle for injecting a high-pressure jet water flow in the vicinity of the tip end portion of the at least one suction pipe and excavating the sediment. There is.

Preferably, the dredging device further comprises a high pressure jet water flow distribution duct that distributes the high pressure jet water flow to the high pressure jet water jet jet nozzle, the high pressure jet water flow distribution duct on the outer surface of at least one suction pipe. It is configured to be arranged along the line.

Preferably, the dredging device further comprises a high pressure jet water flow distribution duct that distributes the high pressure jet water flow to the high pressure jet water jet jet nozzle, and the high pressure jet water flow distribution duct is arranged inside the at least one suction pipe. It is said that it is installed.

Preferably, the casing includes a laterally enlarged skirt portion at the bottom, and the at least one suction tube is configured to extend downward from the skirt portion.

Preferably, the dredging device further comprises at least one vibration absorbing tube for absorbing the vibration of the at least one suction tube, and the casing joins the at least one suction tube to its lower surface. It has at least one suction pipe joint, and the at least one suction pipe is joined to the at least one suction pipe joint via the at least one vibration absorption tube.

Preferably, the submersible pump is configured to be a submersible sand pump in which an impeller and a motor for rotating the impeller are built in and the rotation of the impeller is used as a driving force source.

Preferably, the submersible pump is configured to be a jet lift pump using a high-pressure jet water flow as a driving force source.

Preferably, the submersible pump is configured to be an air lift pump using air as a driving force source.

Preferably, a plurality of the at least one suction tubes are provided, and the structure looks like an octopus as a whole.

According to the present invention, even if obstacles such as sunken trees are mixed in the sediment accumulated in rivers, harbors, dams, lakes and marshes, the impact on the environment is suppressed to a small extent, and the sediment is efficiently excavated and removed. A dredging device capable of working can be provided.

Other features and advantages of the present invention can be further clarified from the following description of embodiments of the invention with reference to the accompanying drawings.

It is a schematic cross-sectional view which shows the dredging system including the dredging apparatus which concerns on 1st Embodiment of this invention. It is a perspective view which shows the dredging device of FIG. It is sectional drawing which follows the line III-III of FIG. It is a figure for demonstrating an example of the dredging work using the dredging system shown in FIG. 1, and is the schematic cross-sectional view which shows the state which the dredging system is deposited on the dam lake, and is arranged above the sediment with mixed sediments. .. Similarly, it is a schematic cross-sectional view showing a state in which the dredging device is lowered to the sediment. Similarly, it is a schematic cross-sectional view showing a state of excavating and removing sediment by a dredging device. It is a perspective view which shows the dredging apparatus which concerns on 2nd Embodiment of this invention. It is a perspective view which shows the dredging apparatus which concerns on 3rd Embodiment of this invention. It is sectional drawing which shows the dredging apparatus which concerns on 4th Embodiment of this invention. It is sectional drawing which shows the dredging apparatus which concerns on 5th Embodiment of this invention. It is sectional drawing which shows the dredging apparatus which concerns on 6th Embodiment of this invention. It is sectional drawing which follows the XII-XII line of FIG.

Hereinafter, preferred embodiments of the present invention will be specifically described with reference to the drawings. In the following description, directions such as the vertical direction shall be in accordance with the description in the drawings.

<First Embodiment>
[Dredging system]
The dredging system DS including the dredging device 1 according to the first embodiment of the present invention is used for dredging sediment S deposited in rivers, harbors, dams, lakes and marshes. As shown in FIG. 1, the dredging system DS includes a dredging device 1, a dredging pontoon 2, a hanging gantry 3, a generator 4, a sediment storage pontoon 2A, a sediment storage tank 5, and a discharge hose. It includes a 5a, a discharge pump 6, and a high-pressure jet water flow supply hose 6a.

The dredging device 1 is connected to the sediment storage tank 5 by a discharge hose 5a, excavates and sucks the sediment S, and performs discharge processing via the discharge hose 5a as shown by an arrow N3. Is. The dredging pontoon 2 is for moving and supporting the dredging device 1 on the water during the dredging work. The dredging pontoon 2 has a configuration in which a plurality of float units 20 having a substantially square shape in a plan view are combined. Further, a pump frame 21 is provided in the central portion as an opening for lowering the dredging device 1 into water. The pump frame 21 is formed in a size that allows the dredging device 1 to pass through. A hanging stand 3 is installed around the pump frame 21. The hanging stand 3 is for suspending the dredging device 1 in water.

An electric chain block 31 is installed on the ceiling portion 30 of the hanging stand 3. The dredging device 1 is suspended from the electric chain block 31 by a chain 32. The chain 32 is provided with a hook (not shown) at the tip thereof, and suspends the dredging device 1. The electric chain block 31 lowers the dredging device 1 into the water in the direction indicated by the arrow N1 and raises it in the direction indicated by the arrow N2.

The generator 4 is installed on the dredging pontoon 2, and includes a generator main body 40 and power supply cables 41 and 42. Power supply cables 41 and 42 are connected to the dredging device 1 and the discharge pump 6 from the generator main body 40. The power supply cable 41 supplies electric power for driving to the dredging device 1. The dredging device 1 sucks and discharges the excavated sediment S together with the surrounding water by this electric power as shown by the arrow N3.

The sediment storage tank 5 is a tank for storing the sediment S sucked and discharged by the dredging device 1, and has a structure in which the lower portion is submerged in water. A discharge pump 6 is installed in the sediment storage tank 5. The discharge pump 6 is connected to the dredging device 1 by a high-pressure jet water flow supply hose 6a described later, and supplies the high-pressure jet water flow to the dredging device 1 as shown by an arrow N4. The high-pressure jet water flow is used when the dredging device 1 excavates the sediment S. The discharge pump 6 is connected to the generator 4 by a power supply cable 42, and receives power for driving from the generator 4.

The sediment storage vessel 2A is configured to move in connection with the dredging vessel 2, and is formed by combining a plurality of float units 22. The float unit 22 has, for example, a U-shape in a plan view. Two float units 22 surround the outer peripheral portion of the sediment storage tank 5 so as to sandwich it from two directions. A protrusion 50 is provided on the outer peripheral portion of the sediment storage tank 5. The sediment storage tank 5 floats on the water surface when the protrusion 50 engages with the upper surface 22a of the float unit 22.

The discharge hose 5a extends from the dredging device 1 toward the sediment storage tank 5, and is used to discharge the sediment S excavated and sucked by the dredging device 1 to the sediment storage tank 5. .. As the discharge hose 5a, for example, a resin bellows-shaped hose is used. The water discharged together with the sediment S into the sediment storage tank 5 is used by the discharge pump 6 to generate a high-pressure jet water flow. That is, in the dredging system DS, the water sucked by the dredging device 1 is reused. Therefore, in the sediment storage tank 5, the tip of the discharge hose 5a and the discharge pump 6 are arranged so as to be appropriately separated from each other, and the discharge pump 6 is the sediment S stored in the sediment storage tank 5. It is configured to prevent accidental suction.

The high-pressure jet water flow supply hose 6a is for connecting the discharge pump 6 and the dredging device 1. It is used to send the high pressure jet water flow generated by the discharge pump 6 to the dredging device 1. As the high-pressure jet water flow supply hose 6a, for example, a resin bellows hose is used.

[Dredging device]
As shown in any of FIGS. 1 to 3, the dredging device 1 includes a casing 10, a submersible sand pump 11, a suction pipe 13, a discharge duct 14, a high-pressure jet water flow supply duct 15, a vibration generator 16, and a vibration absorption pipe. 17 is provided. The dredging device 1 is a casing-type dredging device in which a submersible sand pump 11 is built in a casing 10. The casing 10 is formed by a pump storage pipe 10a and a skirt portion 10m. When the skirt portion 10m is not provided, the casing 10 is formed only by the pump storage pipe 10a. The dredging device 1 excavates the sediment S and removes the excavated sediment S from rivers, harbors, dams, lakes and marshes by sucking and discharging the excavated sediment S together with the surrounding water W as shown by an arrow N3.

The casing 10 accommodates a submersible sand pump 11, a discharge duct 14, and a high-pressure jet water flow supply duct 15 inside a cylindrical pump storage pipe 10a. An opening 10b for maintenance work is formed on the side surface of the pump storage pipe 10a. A maintenance hatch 10c is attached to the opening 10b so as to be openable and closable. The maintenance hatch 10c is fixed with bolts and nuts so that it cannot be easily opened except during maintenance work. The installation work of the submersible sand pump 11 described later is performed through the two openings 10b by opening the maintenance hatch 10c provided so as to face the side surface of the pump storage pipe 10a. Maintenance work for the submersible sand pump 11, the discharge duct 14, the high pressure jet water supply duct 15, and other components is also performed through these openings 10b.

A plurality (for example, four) hook engaging portions 10d for suspending the entire dredging device 1 by the electric chain block 31 are provided at the upper end of the outer peripheral surface of the pump storage pipe 10a. The discharge duct 14 of the submersible sand pump 11 penetrates the upper surface of the pump storage pipe 10a. The discharge duct 14 is connected to the discharge hose 5a. Further, at a position near the center of the upper surface of the pump storage pipe 10a, an attachment portion 10e of a power supply cable 41 for supplying power to the submersible sand pump 11 is provided. A slit (not shown) for taking in the replacement water is formed between the upper surface and the side surface of the pump storage pipe 10a.

The submersible sand pump 11 corresponds to an example of the submersible pump according to the present invention, and includes a motor accommodating portion 11a, an impeller accommodating portion 11b, and a sediment suction portion 11c. The motor (not shown) housed in the motor accommodating portion 11a rotates the impeller (not shown) housed in the impeller accommodating portion 11b by the electric power supplied by the power supply cable 41. The sediment suction portion 11c is provided with a suction port 11d. A suction force is generated by the rotation of the impeller, and a mixture of sediment S and water W is sucked from the suction port 11d as shown by an arrow N3. A stirring blade 11e is attached to the lower part of the suction portion 11c. The stirring blade 11e rotates with the rotation of the impeller, and agitates and homogenizes the sediment S and water W sucked into the dredging device 1. The dredging device 1 sucks and discharges the sediment S having a maximum grain size of about 60 mm by the submersible sand pump 11.

The submersible sand pump 11 is attached to the inner center of the pump storage pipe 10a of the casing 10. The attachment is performed by using the tightening rings 10f and 10j and the connecting plates 10g and 10k to support the motor accommodating portion 11a and the suction portion 11c of the submersible sand pump 11. Specifically, the tightening ring 10f is formed by flange-bonding four tightening ring pieces in the circumferential direction of the motor accommodating portion 11a. The flange coupling portion of the tightening ring 10f is connected to the inner end portion of the connecting plate 10g. On the other hand, the outer end portion of the connecting plate 10g is fixed to the mounting plate 10i provided on the pump support frame 10h. Similarly, the suction portion 11c is supported by the tightening ring 10j and the connecting plate 10k.

A skirt portion 10m is arranged below the pump storage pipe 10a. The skirt portion 10m has a shape that is enlarged in the lateral direction from the pump storage pipe 10a, and is connected to the pump storage pipe 10a by a bolt 10n. A suction pipe joint portion 10p is provided on the lower surface of the skirt portion 10m. The suction pipe joint portion 10p is a cylindrical protrusion protruding downward. The suction pipe 13 is joined to the suction pipe joint portion 10p via a vibration absorbing pipe 17, which will be described later. As shown by the arrow N3, the sediment S sucked by the suction pipe 13 flows into the skirt portion 10 m. The suction pipe joint portion 10p is prepared according to the quantity of the suction pipe 13. If the skirt portion 10m is not provided, a suction pipe joining portion 10p is provided on the lower surface of the pump storage pipe 10a, and the suction pipe 13 is joined.

The suction pipe 13 has a cylindrical shape, is formed thinner than the casing 10, and is made of steel having a diameter of φ100 mm to φ150 mm, preferably φ100 mm to φ125 mm, a length of 2 to 5 m, and preferably 2 to 3 m. The tip portion 13a of the suction pipe 13 has a tapered shape that becomes thinner toward the tip by being cut diagonally, and the tapered surface has an elliptical opening 13b. The dredging device 1 includes four suction pipes 13 and has an octopus-like appearance as a whole. The number of suction tubes 13 is not limited to four, and at least one may be sufficient, and a plurality of suction tubes 13, three, five, six, seven, eight, nine, ten, or more. It may be. When an obstacle such as a sinking tree S1 is mixed in the sediment S, the tip portion 13a of the suction pipe 13 enters the gap of the sinking tree S1 or the like and descends while pushing away the sinking tree S1 or the like. The sediment S is selectively sucked from the opening 13b of the suction pipe 13 together with the surrounding water W.

The high-pressure jet water flow supply duct 15 is for sending the high-pressure jet water flow inside the dredging device 1 as indicated by the arrow N4, and is an upper high-pressure jet water flow supply duct 15a, an annular high-pressure jet water flow supply duct 15b, and a high-pressure jet water flow. It is provided with a distribution duct 15c and a high-pressure jet water jet jet nozzle 15d. The upper high-pressure jet water flow supply duct 15a has a diameter of about φ100 mm, penetrates the upper surface of the pump storage pipe 10a, and is connected to the high-pressure jet water flow supply hose 6a. The upper high-pressure jet water flow supply duct 15a has a reducer and is narrowed in the pump storage pipe 10a, and its diameter is about φ40 mm.

The other end of the upper high-pressure jet water flow supply duct 15a is joined to the annular high-pressure jet water flow supply duct 15b. The annular high-pressure jet water flow supply duct 15b is arranged in an annular shape along the inner peripheral surface at an intermediate height of the pump storage pipe 10a. Its diameter is about φ40 mm. A plurality of high-pressure jet water flow distribution ducts 15c are vertically installed at appropriate intervals from the annular high-pressure jet water flow supply duct 15b. The high-pressure jet water flow distribution duct 15c is for distributing the high-pressure jet water flow to each suction pipe 13, and is prepared according to the number of suction pipes 13. When there is one suction pipe 13, only one high-pressure jet water flow distribution duct 15c is required. The vertically installed high-pressure jet water flow distribution duct 15c is arranged downward so as to penetrate the lower surface of the skirt portion 10m and along the outer surface of the suction pipe 13. The diameter of the high-pressure jet water flow distribution duct 15c is about φ25 mm.

An angle member 13c is welded to the outer surface of the suction pipe 13 in the vertical direction. A high-pressure jet water flow distribution duct 15c is housed therein and is arranged along the outer surface of the suction pipe 13. The high-pressure jet water jet nozzle 15d is for injecting the high-pressure jet water flow in the direction indicated by the arrow N4, is connected to the lower end of the high-pressure jet water flow distribution duct 15c, and is in the vicinity of the opening 13b of the suction pipe 13. It is arranged downward. When the discharge pump 6 is driven by the generator 4 to inject the high-pressure jet water flow from the high-pressure jet water jet nozzle 15d, the sediment S is excavated and agitated at the same time. Then, the sediment S is sucked from the opening 13b of the suction pipe 13 together with the surrounding water W.

A vibrating device 16 is installed on the upper part of the suction pipe 13. The vibrating device 16 vibrates the suction pipe 13 when excavating the sediment S, and assists the suction pipe 13 to enter the gap between obstacles such as the sinking tree S1 mixed in the sediment S and push them away. It generates vibration by using a high-pressure jet water flow as a driving force, and has a high-pressure jet water flow introduction duct 16a and a high-pressure jet water flow outlet 16b. The high-pressure jet water flow introduction duct 16a is branched from the high-pressure jet water flow distribution duct 15c, and introduces the high-pressure jet water flow into the vibrating device 16 as shown by an arrow N5. The high-pressure jet water flow outlet 16b is for flowing out the high-pressure jet water flow used for generating vibration. The vibrating device 16 corresponds to an example of the auxiliary device referred to in the present invention. Further, the vibration corresponds to an example of the assisting movement in the present invention.

Examples of the type of the vibrating device 16 include a roller vibrator that rotates a roller (not shown) built in by a high-pressure jet water flow. In addition, a ball vibrator, a turbine vibrator, a piston vibrator, etc. that rotate a ball, a turbine, or the like by a high-pressure jet water flow or drive a piston can be mentioned. Further, the vibrating device 16 is not limited to one that uses a high-pressure jet water flow as a driving force, and for example, one that uses air pressure may be used. Further, a vibration motor that generates vibration by the exciting force of an unbalanced weight attached to the rotating shaft of the motor may be used.

The suction pipe 13 is joined to the suction pipe joint portion 10p via the vibration absorption pipe 17. The material of the vibration absorbing tube 17 is, for example, rubber. The vibration absorbing pipe 17 is for making it difficult for the vibration generated in the suction pipe 13 by the vibration device 16 to be transmitted to the skirt portion 10m and the pump storage pipe 10a. Further, the vibration absorbing pipe 17 makes the suction pipe 13 swingable as shown by an arrow N6. When an obstacle such as a sinking tree S1 is mixed in the sediment S, the tip portion 13a of the suction pipe 13 enters the gap of the sinking tree S1 or the like, pushes away the sinking tree S1 or the like, and descends while avoiding it. The vibration absorbing pipe 17 is prepared according to the quantity of the suction pipe 13. When there is one suction tube 13, only one vibration absorbing tube 17 is required. As described above, the vibration absorbing tube 17 may have at least one as well as the suction tube 13, and may have two, three, five, six, seven, eight, nine, ten, or more. It may be a plurality of these.

[Dredging method]
An example of dredging work of the dam lake AL using the dredging system DS1 will be described. As shown in FIG. 4, the dam lake AL is dammed by the dam 7. The dam 7 is provided with an intake port 70. An iron grid 71 is fitted in the front surface of the water intake 70. The grid 71 is for preventing large dust from entering the intake 70. Sedimentary sediment S, which is a deposit of sediment flowing from the upstream, is accumulated on the bottom of the dam lake AL. If the sediment S accumulates in the dam lake AL, the amount of water stored may decrease and the intake 70 may be clogged. Obstacles such as the sunken tree S1 that has flowed along with the sediment are mixed in the sediment S.

First, as shown in FIG. 4, in a state where the dredging device 1 is suspended near the ceiling portion 30 of the hanging gantry 3, the dredging pontoon 2 and the sediment storage pontoon 2A are set to the target points by a push ship or the like. Move to.

Next, as shown in FIG. 5, the dredging device 1 is lowered into the water by the electric chain block 31 perpendicularly to the direction indicated by the arrow N1. When the suction pipe 13 reaches the bottom of the water, this is detected by a sensor (not shown) arranged near the tip portion 13a of the suction pipe 13, and the discharge pump 6 and the submersible sand pump 11 start driving. The high-pressure jet water flow generated by the discharge pump 6 that has started driving is jetted from the high-pressure jet water flow injection nozzle 15d via the high-pressure jet water flow supply hose 6a and the high-pressure jet water flow supply duct 15 in the direction indicated by the arrow N4, and the sediment S To excavate. At that time, the sediment S is finely crushed and floats.

As shown in FIGS. 3 and 5, the floating sediment S is sucked together with the water W from the opening 13b of the suction pipe 13 in the direction indicated by the arrow N3 by the suction force generated by the submersible sand pump 11. It is collected in the skirt portion 10 m via the suction tube 13. The sediment S collected in the skirt portion 10 m is made uniform by the stirring blade 11e. The homogenized mixture of sediment S and water W is sucked into the submersible sand pump 11 from the suction port 11d and discharged to the sediment storage tank 5 via the discharge duct 14 and the discharge hose 5a.

Next, as shown in FIG. 6, the dredging device 1 digs down the bottom of the dam lake AL as shown by an arrow N1 while sucking and discharging a mixture of sediment S and water W. The sediment S contains a sunken tree S1, and the dredging device 1 vibrates the suction pipe 13 to enter between the sunken trees S1 and move downward while pushing away or avoiding them. When the dredging device 1 descends by the length of the suction pipe 13 and becomes more difficult to descend, the electric chain block 31 is driven to temporarily lift the dredging device 1 upward as shown by the arrow N2, and the dredging stand is used. The ship 2 and the sediment storage pontoon 2A are moved laterally to the next point.

At that position, the dredging device 1 is lowered again in the direction indicated by the arrow N1 to excavate and remove the sediment S. The sunken trees S1 and the like remaining at the position where the sediment S was previously removed are removed using a heavy machine or the like. Even at the position where the sunken tree S1 and the like are removed, the sediment S is dredged to a depth exceeding the length of the suction pipe 13 by repeatedly excavating and removing the sediment S as necessary. In the same way, the excavation and removal work of the sediment S in the dredged section is repeated to the desired depth.

According to the present embodiment, the dredging device 1 includes a suction pipe 13 below the casing 10. The suction pipe 13 is thinner than the casing 10, and the tip portion 13a has a pointed shape that is thin toward the tip due to an oblique cut. Therefore, even when a large amount of settled trees S1 are mixed in the sediment S of the dam lake AL, the tip portion 13a of the suction pipe 13 enters between the settled trees S1 and pushes away the settled trees S1 while opening the opening 13b. Sedimentary sediment S is selectively sucked from. As a result, the dredging device 1 can descend to a deep place while excavating, sucking, and discharging the sediment S even when obstacles such as the sunken tree S1 are mixed, so that the dredging of the sediment S can be dredged. Work can be done efficiently. As a result, the construction period can be shortened and the cost can be reduced.

Further, since the tip portion 13a has a shape that narrows toward the tip, it is possible to efficiently perform an operation of entering between the sinking trees S1 and pushing away the sinking tree S1.

Further, the suction pipe 13 is provided with a high-pressure jet water jet nozzle 15d in the vicinity of the opening 13b of the tip portion 13a. When the high-pressure jet water jet is jetted from the high-pressure jet water jet nozzle 15d, the sediment S is excavated and agitated at the same time, and is sucked together with the water W from the opening 13b of the suction pipe 13. Therefore, even if the sediment S is considerably hard or highly viscous, it can be discharged. Since the high-pressure jet water jet nozzle 15d is arranged in the vicinity of the opening 13b of the suction pipe 13, turbid water is unlikely to be generated. As a result, dredging work that does not easily affect the environment can be performed.

Further, the high-pressure jet water flow distribution duct 15c is housed in an angle member 13c welded vertically to the outer surface of the suction pipe 13. Therefore, the high-pressure jet water flow distribution duct 15c is arranged along the outer surface of the suction pipe 13. As a result, the high-pressure jet water flow distribution duct 15c can supply the high-pressure jet water flow as shown by the arrow N4 without interfering with the dredging work by the suction pipe 13.

Further, a skirt portion 10m is arranged between the pump storage pipe 10a and the suction pipe 13. The sediment S sucked from the opening 13a of the suction pipe 13 is collected in the skirt portion 10m. The sediment S collected in the skirt portion 10 m is made uniform by the stirring blade 11e. The homogenized mixture of sediment S and water W prevents clogging in the submersible sand pump 11, the discharge duct 14, and the discharge hose 5a, and is smoothly discharged to the sediment storage tank 5. Further, the skirt portion 10 m has a shape that is enlarged in the lateral direction at the lower part of the casing 10. Therefore, more suction tubes 13 can be attached to the lower surface of the skirt portion 10 m. As a result, the efficiency of the dredging work can be improved.

Further, the vibrating device 16 installed on the upper part of the suction pipe 13 vibrates the suction pipe 13 when excavating the sediment S, and the suction pipe 13 removes obstacles such as the sinking tree S1 mixed in the sediment S. By shifting, it helps to push them away. As a result, the dredging device 1 can efficiently excavate, suck, and discharge the sediment S even when obstacles such as the sunken tree S1 are mixed.

Further, the suction pipe 13 is joined to the skirt portion 10 m via the vibration absorbing pipe 17. The vibration absorbing pipe 17 makes it difficult to transmit the vibration generated in the suction pipe 13 by the vibration device 16 to the skirt portion 10m and the pump storage pipe 10a. As a result, it is possible to prevent damage to the pump storage pipe 10a, the submersible sand pump 11 and the like stored in the pump storage pipe 10a due to the generation of vibration, and the skirt portion 10m, and to excavate, suck, and discharge stable sediment S.

Further, the vibration absorbing pipe 17 makes the suction pipe 13 swingable at the suction pipe joint portion 10p on the lower surface of the skirt portion 10m. As a result, the tip portion 13a of the suction pipe 13 can avoid obstacles such as the sunken tree S1. As a result, the suction pipe 13 can descend while avoiding obstacles such as the sunken tree S1, and the efficiency of excavation, suction, and discharge of the sediment S can be improved.

Further, since a plurality of suction pipes 13 are provided, the dredging work of the sediment S can be efficiently performed.

Further, the dredging system DS has a structure in which the dredging device 1 having the suction pipe 13 and the sediment storage tank 5 are compactly connected and can move on the water as a unit, so that the construction site is narrow. Efficiently selective even in places where space is forced, where it is difficult to carry in / out large machines, assemble and install, and where obstacles such as sediment S and sunken trees S1 coexist on the bottom of the water. Sedimentary sediment S can be excavated, sucked, and discharged.

<Second embodiment>
The dredging device 1A according to the second embodiment of the present invention will be described with reference to FIG. 7. In the dredging device 1A, the components having the same or similar functions as the components of the dredging device 1 according to the first embodiment are designated by the same reference numerals as those of the dredging device 1. Detailed description of these will be omitted. As shown in FIG. 7, in the dredging device 1A, in the high-pressure jet water flow supply duct 15A, the high-pressure jet water flow distribution duct 15Ac vertically installed from the annular high-pressure jet water flow supply duct 15b is housed inside the suction pipe 13. It differs from the first embodiment in that the high-pressure jet water jet jet nozzle 15Ad is arranged inside the opening 13b. The high-pressure jet water flow distribution duct 15Ac is for distributing the high-pressure jet water flow to each suction pipe 13, and is prepared according to the number of suction pipes 13. The high-pressure jet water jet nozzle 15Ad is arranged so as to slightly project downward from the opening 13b. However, the high-pressure jet water jet nozzle 15Ad may be arranged at the height of the opening 13b, or may be housed inside the suction pipe 13.

According to the present embodiment, the same effect as that of the first embodiment is obtained.

Further, in the present embodiment, the number of structures installed on the outer surface can be reduced. As a result, the suction pipe 13 can descend to a deep place with little resistance when pushing away the sinking tree S1 while sucking the sediment S. Further, the high-pressure jet water flow distribution duct 15Ac can supply the high-pressure jet water flow as shown by the arrow N4 without interfering with the dredging work by the suction pipe 13.

<Third embodiment>
The dredging device 1B according to the third embodiment of the present invention will be described with reference to FIG. In the dredging device 1B, the components having the same or similar functions as the components of the dredging device 1 according to the first embodiment are designated by the same reference numerals as those of the dredging device 1. Detailed description of these will be omitted. As shown in FIG. 8, in the dredging device 1B, the tip portion 13Ba of the suction tube 13B is formed in a conical pointed shape that becomes thinner toward the tip. This embodiment differs from the first embodiment in this respect. A plurality of elliptical openings 13Bb are formed on the inclined surface of the tip portion 13Ba. The opening 13Bb is for sucking the sediment S. In the high-pressure jet water flow supply duct 15B, the high-pressure jet water flow distribution duct 15Bc vertically installed from the annular high-pressure jet water flow supply duct 15b is housed inside the suction pipe 13B. The high-pressure jet water flow distribution duct 15Bc is for distributing the high-pressure jet water flow to each suction pipe 13B, and is prepared according to the number of suction pipes 13B. A high-pressure jet water jet nozzle 15Bd is arranged in one of the openings 13Bb. The shape of the tip portion 13Ba is not limited to a conical shape, and may be a triangular pyramid, a quadrangular pyramid, a pentagonal pyramid, a hexagonal pyramid, or a larger pyramid.

According to the present embodiment, the same effect as that of the first embodiment is obtained.

Further, in the present embodiment, the number of structures installed on the outer surface can be reduced. Therefore, the suction pipe 13B can descend to a deep place with little resistance when pushing away the sinking tree S1 while sucking the sediment S. Further, since the tip portion 13Ba is formed in a conical pointed shape that becomes thinner toward the tip, it is easy to descend straight. As a result, stable excavation, suction, and discharge of sediment S can be achieved.

<Fourth Embodiment>
The dredging device 1C according to the fourth embodiment of the present invention will be described with reference to FIG. In the dredging device 1C, the components having the same or similar functions as the components of the dredging device 1 according to the first embodiment are designated by the same reference numerals as those of the dredging device 1. Detailed description of these will be omitted.

The dredging device 1C includes a jet lift pump 11C instead of the submersible sand pump 11. The jet lift pump 11C corresponds to another example of the submersible pump referred to in the present invention. The jet lift pump 11C includes a jet lift pump drive pipe 11Ca and a sediment suction portion 11Cc. A suction port 11Cd is provided in the sediment suction portion 11Cc. The jet lift pump drive pipe 11Ca is provided with a high-pressure jet water flow supply unit 11Cb. The high-pressure jet water flow is supplied to the high-pressure jet water flow supply unit 11Cb via the pump-driving high-pressure jet water flow supply duct 15Ce distributed from the annular high-pressure jet water flow supply duct 15b as shown by the arrow N7. A suction force is generated by using this high-pressure jet water flow as a driving force, and as shown by an arrow N3, a mixture of sediment S and water W is sucked from the suction pipe 13, which is further sucked inside the pump storage pipe 10a. It is sucked from the suction port 11Cd of 11Cc.

The jet lift pump 11C is mounted inside the pump storage pipe 10a. The attachment is performed by using the tightening rings 10Cf and 10Cj and the connecting plates 10Cg and 10Ck to support the jet lift pump drive pipe 11Ca and the sediment suction portion 11Cc of the jet lift pump 11C. Specifically, the tightening ring 10Cf is formed by flange-bonding four tightening ring pieces in the circumferential direction of the jet lift pump drive pipe 11Ca. The flange coupling portion of the tightening ring 10Cf is connected to the inner end portion of the connecting plate 10Cg. On the other hand, the outer end portion of the connecting plate 10Cg is fixed to the mounting plate 10i provided on the pump support frame 10h. Similarly, the sediment suction portion 11Cc is supported by the tightening ring 10Cj and the connecting plate 10Ck.

According to the present embodiment, the same effect as that of the first embodiment is obtained.

Further, in the present embodiment, since a structure such as an impeller is not provided inside the jet lift pump 11C, the sediment S containing relatively large grain size (for example, maximum grain size of about 200 mm) is sucked. can do.

Further, the jet lift pump 11C has an extremely simple structure including a jet lift pump drive pipe 11Ca and a high-pressure jet water flow supply duct 15Ce for driving the pump. As a result, the dredging device 1C has an advantage that there are few failures.

<Fifth Embodiment>
The dredging device 1D according to the fifth embodiment of the present invention will be described with reference to FIG. In the dredging device 1D, the components having the same or similar functions as the components of the dredging device 1 according to the first embodiment are designated by the same reference numerals as those of the dredging device 1. Detailed description of these will be omitted.

The dredging device 1D includes an air lift pump 11D instead of the submersible sand pump 11. The air lift pump 11D corresponds to another example of the submersible pump referred to in the present invention. The air lift pump 11D includes a pumping pipe 11Da and a sediment suction unit 11Dc. The sediment suction portion 11Dc is provided with a suction port 11Dd. The pumping pipe 11Da is provided with an air supply unit 11Db. An air supply duct attachment portion 10De for attaching an air supply duct 11De for supplying air to the air lift pump 11D is provided at a position near the center of the upper surface of the pump storage pipe 10a. The air supply duct 11De is for supplying air from an air pump (not shown) provided outside the dredging device 1D to the air supply unit 11Db as shown by an arrow N8. A suction force is generated by using this air as a driving force, and as shown by an arrow N3, a mixture of sediment S and water W is sucked from the suction pipe 13, which is further inside the pump storage pipe 10a of the sediment suction portion 11Dc. It is sucked from the suction port 11Dd.

The air lift pump 11D is mounted inside the pump storage pipe 10a. The attachment is carried out by using the tightening rings 10Df and 10Dj and the connecting plates 10Dg and 10Dk to support the pumping pipe 11Da of the air lift pump 11D and the sediment suction portion 11Dc. Specifically, the tightening ring 10Df is formed by flange-bonding four tightening ring pieces in the circumferential direction of the air lift pump drive pipe 11Da. The flange joint portion of the tightening ring 10Df is connected to the inner end portion of the connecting plate 10Dg. On the other hand, the outer end portion of the connecting plate 10Dg is fixed to the mounting plate 10i provided on the pump support frame 10h. Similarly, the sediment suction portion 11Dc is supported by the tightening ring 10Dj and the connecting plate 10Dk.

According to the present embodiment, the same effect as that of the first embodiment is obtained.

Further, in the present embodiment, since a structure such as an impeller is not provided inside the air lift pump 11D, the sediment S containing relatively large grain size (for example, maximum grain size of about 200 mm) is sucked. can do.

Further, the air lift pump 11D has an extremely simple structure including a pumping pipe 11Da and an air supply duct 11De. As a result, the dredging device 1D has an advantage that there are few failures.

<Sixth Embodiment>
The dredging device 1E according to the sixth embodiment of the present invention will be described with reference to FIGS. 11 and 12. In the dredging device 1E, the components having the same or similar functions as the components of the dredging device 1 according to the first embodiment are designated by the same reference numerals as those of the dredging device 1. Detailed description of these will be omitted.

As shown in FIG. 11, the dredging device 1E is different from the dredging device 1 in that it includes a rotating device 16E instead of the vibrating device 16. The rotating device 16E corresponds to another example of the auxiliary device according to the present invention. The rotating device 16E is for rotating the suction pipe 13E. The rotating device 16E is installed above the suction pipe 13E. The rotating device 16E rotates the suction pipe 13E as shown by the arrow N9 when excavating the sediment S, and the suction pipe 13E enters between obstacles such as the sinking tree S1 mixed in the sediment S. It is intended to assist in pushing away or avoiding obstacles in the area. Rotation corresponds to another example of assisting movement in the present invention. The rotating device 16E rotates the suction pipe 13E by using the high-pressure jet water flow as a driving force, and has a high-pressure jet water flow introduction duct 16Ea and a high-pressure jet water flow outlet 16Eb. The high-pressure jet water flow introduction duct 16Ea is branched from the high-pressure jet water flow distribution duct 15Ec. The high-pressure jet water flow outlet 16Eb is for flowing out the high-pressure jet water flow used for rotation. The high-pressure jet water flow introduction duct 16Ea supplies the high-pressure jet water flow to the rotating device 16E as indicated by an arrow N10.

In the dredging device 1E, the suction tube 13E is formed in a conical pointed shape in which the tip portion 13Ea becomes thinner toward the tip. A plurality of elliptical openings 13Eb are formed on the inclined surface of the tip portion 13Ea. The opening 13Eb is for sucking the sediment S. In the high-pressure jet water flow supply duct 15E, the high-pressure jet water flow distribution duct 15Ec vertically installed from the annular high-pressure jet water flow supply duct 15b is housed inside the suction pipe 13E. The high-pressure jet water flow distribution duct 15Ec is for distributing the high-pressure jet water flow to each suction pipe 13E, and is prepared according to the number of suction pipes 13E. The high-pressure jet water jet nozzle 15Ed is arranged at the apex of the tip portion 13Ea. The high-pressure jet water flow distribution duct 15Ec is configured not to rotate when the suction pipe 13E is rotating. The shape of the tip portion 13Ea is not limited to a conical shape, and may be a triangular pyramid, a quadrangular pyramid, a pentagonal pyramid, a hexagonal pyramid, or a larger pyramid.

As shown in FIG. 12, a plurality of blades 13Ed are formed on the outer peripheral portion of the suction pipe 13E inside the rotating device 16E. The blade 13Ed receives the high-pressure jet water flow introduced from the high-pressure jet water flow introduction duct 16Ea in the direction indicated by the arrow N10, and rotates the suction pipe 13E in the direction indicated by the arrow N9. By rotating, the suction pipe 13E enters between obstacles such as the sinking tree S1 mixed in the sediment S, pushes away these obstacles, and avoids them. The dredging device 1E descends while excavating, sucking, and discharging the sediment S.

According to the present embodiment, the same effect as that of the first embodiment is obtained.

Further, the rotating device 16E installed on the upper part of the suction pipe 13E rotates the suction pipe 13E when excavating the sediment S, and the suction pipe 13E removes obstacles such as the sinking tree S1 mixed in the sediment S. Assist in pushing away. As a result, the dredging device 1E can efficiently excavate, suck, and discharge the sediment S even when obstacles such as the sunken tree S1 are mixed.

Further, the suction pipe 13E is provided with a high-pressure jet water jet nozzle 15Ed at the apex of the tip portion 13Ea. When the high-pressure jet water jet is jetted from the high-pressure jet water jet nozzle 15Ed, the sediment S is excavated and lifted at the same time, and is sucked together with the water W from the opening 13Eb of the suction pipe 13E. Therefore, even if the sediment S is considerably hard or highly viscous, it can be discharged. In the dredging device 1E, since the high-pressure jet water jet nozzle 15Ed is arranged in the vicinity of the opening 13Eb of the suction pipe 13E, turbid water is less likely to be generated and the environment is less likely to be affected.

The present invention is not limited to the contents of the above-described embodiments. The specific configuration of the dredging device according to the present invention can be freely redesigned. In addition, the features shown in each of the above-described embodiments can be applied to other embodiments as long as they do not contradict each other.

The equipment for suspending the dredging device 1 in water is not limited to the electric chain block 31 provided on the suspension platform 3 installed on the dredging pontoon 2 shown in FIG. For example, a loading crane may be installed on an assembly-type crane carrier, and the dredging device 1 may be lowered or raised in water by the loading crane.

S Sedimentary sediment S1 Sedimentation tree (obstacle)
1,1A, 1B, 1C, 1D, 1E Dredging device 10 Casing 10m Skirt 10p Suction pipe joint 11 Submersible sand pump (submersible pump)
11C jet lift pump (submersible pump)
11D air lift pump (submersible pump)
13, 13B, 13E Suction pipe 13a, 13Ba, 13Ea Tip 13b, 13Bb, 13Eb Opening 15c, 15Ac, 15Bc, 15Ec High-pressure jet water flow distribution duct 15d, 15Ad, 15Bd, 15Ed High-pressure jet water jet nozzle 16 Vibration device (auxiliary) apparatus)
16E rotating device (auxiliary device)
17 Vibration absorption tube

Claims (11)

It is a dredging device for dredging sediment accumulated on the bottom of the water while descending underwater due to the mixture of obstacles such as sunken trees.
Casing and
A submersible pump housed inside the casing for sucking and discharging the sediment.
With at least one suction tube that has a tip provided with an opening, is formed thinner than the casing, and extends downward from the casing.
With
The tip portion sucks the sediment from the opening while entering between the obstacles and pushing away the obstacles .
The at least one suction tube is further provided with an auxiliary device for causing a movement in which the tip portion enters between the obstacles and assists the obstacles to be pushed away.
The auxiliary device is a dredging device that causes vibration and / or rotation of at least one suction pipe as the auxiliary movement. The dredging device according to claim 1, wherein the tip portion has a shape that narrows toward the tip. The dredging device according to claim 1 or 2, further comprising a high-pressure jet water jet nozzle for injecting a high-pressure jet water flow into the vicinity of the tip end portion of the at least one suction pipe and excavating the sediment. The high-pressure jet water jet jet nozzle is further provided with a high-pressure jet water flow distribution duct for distributing the high-pressure jet water flow.
The dredging device according to claim 3 , wherein the high-pressure jet water flow distribution duct is arranged along the outer surface of at least one suction pipe. The high-pressure jet water jet jet nozzle is further provided with a high-pressure jet water flow distribution duct for distributing the high-pressure jet water flow.
The dredging device according to claim 3 , wherein the high-pressure jet water flow distribution duct is arranged inside at least one suction pipe. The casing includes a skirt portion having a laterally enlarged skirt shape at the bottom.
The dredging device according to any one of claims 1 to 5, wherein the at least one suction tube extends downward from the skirt portion. Further comprising at least one vibration absorbing tube for absorbing the vibration of the at least one suction tube.
The casing has at least one suction tube joint for joining the at least one suction tube on its lower surface.
The dredging device according to any one of claims 1 to 6, wherein the at least one suction pipe is joined to the at least one suction pipe joint portion via the at least one vibration absorbing pipe. The dredging device according to any one of claims 1 to 7 , wherein the submersible pump is a submersible sand pump containing an impeller and a motor for rotating the impeller and using the rotation of the impeller as a driving force source. The dredging device according to any one of claims 1 to 7 , wherein the submersible pump is a jet lift pump using a high-pressure jet water flow as a driving force source. The dredging device according to any one of claims 1 to 7 , wherein the submersible pump is an air lift pump using air as a driving force source. The dredging device according to any one of claims 1 to 10 , wherein a plurality of the at least one suction pipe is provided and looks like an octopus as a whole.

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