JP7132051B2 - dredging equipment - Google Patents

Description

The present invention relates to dredging equipment.

BACKGROUND ART As a dredging method for removing sediment deposited on the bottom of water such as rivers, canals, lakes, settling basins, reservoirs, etc., there is known a fluid transportation method using a submersible sand pump (see Patent Document 1).

JP 2015-47522 A

However, although the dredging method of Patent Literature 1 can recover sediment from deep water, it is necessary to excavate and agitate the deposited sediment before sucking it, which pollutes the working environment.

The present disclosure has been made in view of the above, and an object of the present disclosure is to provide a dredging device capable of recovering sediment from deep water and suppressing water contamination.

In order to solve the above-described problems and achieve the object, one aspect of the present disclosure provides a suction nozzle arranged at the bottom of the water, a housing arranged in water, and a first pumping device arranged inside the housing. a pump, a first suction pipe having one end connected to the suction nozzle and the other end connected to the housing, a second suction pipe having one end connected to the housing and the other end disposed above the water, and The dredging device includes a pumping pipe connected to a first pumping pump and the other end of which is placed above the water, and a suction pump which is placed above the water and sucks the second suction pipe.

In addition, in the aspect of the dredging device described above, it is preferable that one end of the second suction pipe is connected to the upper surface of the housing.

In the dredging device described above, the distance from the other end of the first suction tube to the one end of the second suction tube is preferably smaller than the distance from the other end of the first suction tube to the one end of the pumping tube.

In addition, in the aspect of the dredging device described above, it is preferable that the first suction pipe is extendable and bendable.

In addition, in the aspect of the dredging device described above, it is preferable that the suction nozzle includes an injection nozzle for injecting water.

In addition, in the aspect of the dredging device described above, it is preferable that the suction nozzle has a cylindrical portion, and the injection nozzle is provided inside the cylindrical portion.

In addition, in the aspect of the dredging device described above, it is preferable that the suction nozzle is provided with a grid-like protective net covering the suction port.

In addition, in the aspect of the dredging device described above, a recovery tank connected to the other end of the second suction pipe and the other end of the pumping pipe, and a third suction pipe having one end connected to the recovery tank and the other end connected to the suction pump and a suction tube.

In addition, it is preferable to provide the 2nd force-feeding pump which discharges earth and sand from a collection tank in the aspect of said dredging apparatus.

In addition, in the dredging device described above, it is preferable to include a dewatering device for dewatering the earth and sand discharged from the collection tank.

In addition, in the aspect of the dredging device described above, it is preferable that the collection tank is arranged on the barge.

In addition, it is preferable to provide the 1st raising/lowering apparatus which raises/lowers a suction nozzle in the aspect of said dredging apparatus.

In addition, it is preferable to provide the 2nd raising/lowering apparatus which raises/lowers a housing|casing in the aspect of said dredging apparatus.

Advantageous Effects of Invention According to the present disclosure, it is possible to recover mud from deep water and suppress water contamination.

FIG. 1 is a schematic diagram showing the dredging device of the first embodiment. FIG. 2 is a schematic diagram showing the main part of FIG. FIG. 3 is a schematic cross-sectional view showing a suction nozzle. FIG. 4 is a schematic enlarged view showing the suction port of the suction nozzle. FIG. 5 is a schematic diagram showing the dredging device of the second embodiment. FIG. 6 is a schematic diagram showing a modified arrangement example of the dredging device of the second embodiment. FIG. 7 is a schematic diagram showing the dredging device of the third embodiment.

EMBODIMENT OF THE INVENTION Below, embodiment of the dredging apparatus which concerns on this invention is described in detail based on drawing. It should be noted that the present invention is not limited to the description of the following embodiments. In addition, components in the following embodiments include components that can be easily replaced by those skilled in the art, or components that are substantially the same. Furthermore, the components described below can be combined as appropriate. In addition, in the following description of the embodiments, the same configurations are denoted by the same reference numerals, and different configurations are denoted by different reference numerals.

(First embodiment)
FIG. 1 is a schematic diagram showing the dredging device of the first embodiment. FIG. 2 is a schematic diagram showing the main part of FIG. FIG. 3 is a schematic enlarged view showing a suction nozzle. FIG. 4 is a schematic cross-sectional view showing a suction nozzle. The dredging device 10 of the first embodiment is a device for dredging sediment deposited at the bottom of water such as rivers, canals, lakes, settling basins, or reservoirs. Sedimentation includes sludge, mud, etc., with high specific gravity and high viscosity. The dredging device 10 continuously performs underwater suction, vertical transportation, and horizontal transportation of sediment. In 1st Embodiment, the dredging apparatus 10 dredges the sediment D deposited on the bottom part of the reservoir W. As shown in FIG. The dredging device 10 includes a suction nozzle 20, an intermediate unit 30, a recovery tank 40, a suction pump 50, a first suction pipe 60, a second suction pipe 70, a third suction pipe 80, and a pumping pipe 90. , a lifting device 100 , a second compressing pump 110 , a dewatering device 120 and a conveying pipe 130 . In the dredging device 10, a lifting device 100 is arranged on a barge B floating in a reservoir W. The recovery tank 40 , the suction pump 50 , the second pressure-feeding pump 110 and the dewatering device 120 are arranged in the land portion G.

The suction nozzle 20 is arranged at the bottom of the reservoir W. As shown in FIG. 2, the suction nozzle 20 has a suction port 22 at one end 20A. The suction port 22 is inserted into the sediment D deposited on the water bottom of the reservoir W. The suction nozzle 20 sucks the sediment D from the suction port 22 . The other end 20B of the suction nozzle 20 is connected to one end 60A of the first suction tube 60 . The gap between the suction nozzle 20 and the first suction pipe 60 is sealed. The sediment D sucked by the suction nozzle 20 passes through the first suction pipe 60 and is conveyed in the direction of the other end 60B of the first suction pipe 60 as the sand D1.

FIG. 3 is a schematic cross-sectional view showing a suction nozzle. As shown in FIG. 3, the suction nozzle 20 includes a tubular portion 20T and an injection nozzle 24. As shown in FIG. The injection nozzle 24 is provided inside a cylindrical portion 20T that serves as a flow path for the earth and sand D1 in the suction nozzle 20 . The jet nozzle 24 jets water from inside the suction nozzle 20 toward the suction port 22 . As a result, the jetted water from the jet nozzle 24 separates foreign objects such as driftwood and clumps of mudstone that cannot be sucked from the suction port 22 from the suction port 22 . The pressure of the water jet is greater than the suction force of the suction nozzle 20 . The injection nozzle 24 preferably has a variable injection direction. Thereby, the injection nozzle 24 can inject water toward the entire suction port 22 . A drive device for driving the injection nozzle 24 is arranged above the water of the reservoir W, for example. Water is supplied to the injection nozzle 24 from a water supply pipe 26 . The water supply pipe 26 may be supplied with water from a reservoir W, for example.

FIG. 4 is a schematic enlarged view showing a suction nozzle. As shown in FIG. 4, the suction nozzle 20 is provided with a protective net 28. As shown in FIG. The protection net 28 is a lattice net. A protective net 28 covers the suction port 22 . The protection net 28 suppresses foreign matter from entering the suction nozzle 20 . The mesh of the guard net 28 is preferably less than 1/3 the inner diameter of the pumping tube 90 shown in FIGS. As a result, foreign matter having a size of ⅓ or more of the inner diameter of the pressure-feeding pipe 90 is prevented from entering.

As shown in FIG. 2 , the intermediate unit 30 includes a substantially rectangular parallelepiped housing 32 and a first pressure-feeding pump 34 . The housing 32 is placed in the water of the reservoir W. The interior of the housing 32 is sealed from the water of the reservoir W. The housing 32 has an opening 32A and an opening 32B. 32 A of openings are arrange|positioned at the bottom face of the housing|casing 32. As shown in FIG. The opening 32A may be arranged on the side of the housing 32 . The housing 32 is connected to the other end 60B of the first suction tube 60 at the opening 32A. The gap between the housing 32 and the first suction tube 60 is sealed. The housing 32 is connected to the suction nozzle 20 via the first suction tube 60 . The housing 32 collects the earth and sand D1 conveyed by the first suction pipe 60 . The opening 32B is arranged on the upper surface of the housing 32 . The housing 32 is connected to one end 70A of the second suction tube 70 at the opening 32B. The gap between the housing 32 and the second suction tube 70 is sealed. The first compressing pump 34 is arranged inside the housing 32 . The first pressure-feeding pump 34 is, for example, a positive displacement slurry pump. The first compressing pump 34 is connected to one end 90A of the compressing pipe 90 . The gap between the first pressure-feeding pump 34 and the pressure-feeding pipe 90 is sealed. The first pressure-feeding pump 34 pressure-feeds the earth and sand D1 to the pressure-feeding pipe 90 . The earth and sand D1 collected in the housing 32 is conveyed through the force-feeding pipe 90 toward the other end 90B of the force-feeding pipe 90 as the earth and sand D2. A portion of the earth and sand D1 collected in the housing 32 is conveyed as earth and sand D2 through the second suction pipe 70 toward the other end 70B of the second suction pipe 70 .

The collection tank 40 is arranged above the water of the reservoir W. The inside of the recovery tank 40 is sealed from the outside air. The recovery tank 40 is connected to the other end 70B of the second suction pipe 70 . The gap between the collection tank 40 and the second suction pipe 70 is sealed. The collection tank 40 is connected to the housing 32 via the second suction pipe 70 . The collection tank 40 collects the earth and sand D2 conveyed by the second suction pipe 70 . The recovery tank 40 is connected to the other end 90B of the pumping pipe 90 . The gap between the collection tank 40 and the pressure feed pipe 90 is sealed. The recovery tank 40 is connected to the housing 32 via the pressure-feeding pipe 90 and the first pressure-feeding pump 34 . The collection tank 40 collects the earth and sand D2 conveyed by the pressure feed pipe 90 . The recovery tank 40 is connected to one end 80A of the third suction pipe 80 . The gap between the recovery tank 40 and the third suction pipe 80 is sealed.

The suction pump 50 is arranged above the water of the reservoir W. The suction pump 50 is, for example, a vacuum pump. The maximum air volume at the intake port 50A of the suction pump 50 is, for example, 100 m ³ /min. An intake port 50A of the suction pump 50 is connected to the other end 80B of the third suction pipe 80 . The gap between the suction pump 50 and the third suction pipe 80 is sealed. The suction pump 50 is connected to the collection tank 40 via the third suction pipe 80 .

The inner diameters of the first suction tube 60 , the second suction tube 70 and the third suction tube 80 are larger than the inner diameter of the pumping tube 90 . The inner diameters of the first suction tube 60, the second suction tube 70 and the third suction tube 80 are, for example, 200 mm. The inner diameter of the pumping tube 90 is, for example, 100 mm.

The suction pump 50 sucks the second suction pipe 70 through the third suction pipe 80 and the recovery tank 40 . Thereby, the negative pressure is maintained inside the housing 32 , the first suction pipe 60 and the suction nozzle 20 . The interior of the housing 32 preferably maintains a high degree of vacuum. The suction pump 50 causes the suction nozzle 20 to suck the sediment D by the negative pressure, and transports the dirt D1 from the suction nozzle 20 to the housing 32 . The housing 32 is installed at a first height h1 from the suction port 22 of the suction nozzle 20 . Here, the height at which suction by negative pressure is possible is 10 m (760 mmHg) even under absolute vacuum conditions according to Torricelli's vacuum principle. Therefore, the first height h1 is less than 10m, preferably 8m or less.

The first pressure-feeding pump 34 pressure-feeds the earth and sand D1 inside the housing 32 to the pressure-feeding pipe 90 . The first pressure-feeding pump 34 pressure-feeds the earth and sand D2 from the housing 32 to the recovery tank 40 . The force by which the first pressure feed pump 34 pushes the earth and sand D1 inside the housing 32 is greater than the force by which the suction pump 50 pulls the air inside the housing 32 . The recovery tank 40 is installed at a position where the other end 90B of the pumping pipe 90 is at the second height h2 from the housing 32 . The second height h2 is, for example, 15m. The second height h2 and the horizontal distance h3 from the first pressure-feeding pump 34 to the other end 90B of the pressure-feeding pipe 90 depend on the performance of the first pressure-feeding pump 34 . The recovery tank 40 can also be installed at a position where the horizontal distance h3 is 100 m or more.

In the first embodiment, the distance from the other end 60B of the first suction tube 60 in the housing 32 to the one end 70A of the second suction tube 70 is the distance from the other end 60B of the first suction tube 60 to the one end 90A of the pumping tube 90. less than the distance of As a result, an airflow from the other end 60B of the first suction tube 60 to the one end 70A of the second suction tube 70 is generated. Inside the second suction pipe 70 , an airflow is generated from one end 70A to the other end 70B by suction by the suction pump 50 . A part of the earth and sand D1 collected in the housing 32 rides on the air current inside the second suction pipe 70 and is transported to the collection tank 40 as the earth and sand D2.

The lifting device 100 shown in FIG. 1 is a telescopic clam backhoe in the first embodiment. The lifting device 100 has a main body 102 , a boom 104 swingable with respect to the main body 102 , and an arm 106 swingable with respect to the boom 104 and telescopic. A tip of the arm 106 is fixed to the housing 32 of the intermediate unit 30 . The lifting device 100 lifts and lowers the suction nozzle 20 , the first suction pipe 60 and the housing 32 by extending and retracting the arm 106 . The lifting device 100 supports the housing 32 in the water of the reservoir W, and inserts the suction port 22 of the suction nozzle 20 into the sediment D on the bottom of the reservoir W.

The second pressure-feeding pump 110 is, for example, a positive displacement slurry pump. The second compressing pump 110 is connected to the discharge portion 42 of the recovery tank 40 and one end 130A of the conveying pipe 130 . The second pressure-feeding pump 110 takes in the earth and sand D2 from the discharge portion 42 of the collection tank 40 and pressure-feeds it toward the other end 130B of the conveying pipe 130 . The earth and sand D2 collected in the collection tank 40 is conveyed through the conveying pipe 130 in the direction of the other end 130B of the conveying pipe 130 as the earth and sand D3.

The dehydrator 120 is connected to the other end 130B of the carrier pipe 130 . The dehydrator 120 collects the earth and sand D3 conveyed by the conveying pipe 130 and performs solid-liquid separation to separate the earth and sand D3 into solid and water. The separated solids are transported, for example, to a sand dump. The separated water is returned to the reservoir W, for example, after being purified by a waste water treatment facility or the like. In the first embodiment, the earth and sand D2 collected in the collection tank 40 is dehydrated by the dehydrator 120, but may be dehydrated by, for example, a solar drying treatment facility.

As described above, the dredging device 10 of the first embodiment includes the suction nozzle 20 arranged on the bottom of the water, the housing 32 arranged in the water, and the first force feeding pump 34 arranged inside the housing 32. a first suction pipe 60 having one end 60A connected to the suction nozzle 20 and the other end 60B connected to the housing 32; 2 suction pipes 70, a pressure-feeding pipe 90 having one end 90A connected to the first pressure-feeding pump 34 and the other end 90B arranged above water, a suction pump 50 arranged above water and sucking the second suction pipe 70, Prepare.

As a result, the dredging device 10 dredges from the suction nozzle 20 to the housing 32 of the intermediate unit 30 by suction of the suction pump 50 , and dredges from the housing 32 to the surface of the water by pressure feeding of the first pressure-feeding pump 34 . That is, the heavy sediment D (earth and sand D1) is collected by suction, and the high-height earth and sand D2 is conveyed by pumping, so that mud in deep water can be collected and water contamination can be suppressed. Further, the sucked earth and sand D1 does not contain excess water, and can be collected at a high concentration of about 20 to 50% of the mud content.

One end 70A of the second suction pipe 70 of the dredging device 10 is connected to the upper surface of the housing 32 .

According to such a dredging device 10, it is possible to suppress clogging of the second suction pipe 70 with the earth and sand D1.

In the dredging device 10, the distance from the other end 60B of the first suction pipe 60 to the one end 70A of the second suction pipe 70 is smaller than the distance from the other end 60B of the first suction pipe 60 to the one end 90A of the pumping pipe 90.

According to such a dredging device 10, an airflow is generated from the suction nozzle 20 toward the other end 70B of the second suction pipe 70 through the first suction pipe 60, the housing 32 and the second suction pipe 70. Thereby, the second suction pipe 70 can convey part of the earth and sand D1 collected in the housing 32 .

In the dredging device 10, the suction nozzle 20 is provided with an injection nozzle 24 for injecting water.

According to the dredging device 10 as described above, the pressure of the jet water keeps clumps such as driftwood and mudstone away from the suction port 22, so that the suction port 22 can be prevented from being clogged with foreign matter.

In the dredging device 10, the suction nozzle 20 has a tubular portion 20T, and the injection nozzle 24 is provided inside the tubular portion 20T.

According to such a dredging device 10, clogging of the suction port 22 by foreign matter can be suppressed more preferably.

In the dredging device 10 , the suction nozzle 20 is provided with a grid-like protective net 28 covering the suction port 22 .

According to the dredging device 10 as described above, clogging of the inside of the first suction pipe 60 , the second suction pipe 70 and the pressure feed pipe 90 due to foreign matter entering the suction nozzle 20 can be suppressed.

The dredging device 10 includes a collection tank 40 connected to the other end 70B of the second suction pipe 70 and the other end 90B of the pressure feed pipe 90, and a collection tank 40 connected to the collection tank 40 at one end 80A and connected to the suction pump 50 at the other end 80B. and a third suction tube 80 .

According to the dredging device 10 as described above, since the earth and sand D2 are collected in the collection tank 40, the invasion of the earth and sand D2 into the suction pump 50 can be suppressed.

The dredging device 10 includes a second pressure-feeding pump 110 that discharges the earth and sand D2 from the recovery tank 40 .

According to the dredging device 10 as described above, since the earth and sand D2 collected in the collection tank 40 are sequentially discharged, the efficiency of dredging by the suction pump 50 and the first pressure feed pump 34 can be maintained.

The dredging device 10 includes a dewatering device 120 for dewatering the earth and sand D3 discharged from the recovery tank 40 .

According to such a dredging device 10, the discharged earth and sand D3 can be treated more favorably.

(Second embodiment)
FIG. 5 is a schematic diagram showing the dredging device of the second embodiment. In the dredging device 10A shown in FIG. 5, the same reference numerals are given to the same configurations as those of the dredging device 10 shown in FIG. The dredging device 10A includes a first suction pipe 60F, a first lifting device 140 and a second lifting device 150 instead of the first suction pipe 60 and the lifting device 100 in the dredging device 10. In the dredging device 10A, the recovery tank 40, the suction pump 50, the second compressing pump 110, the first lifting device 140 and the second lifting device 150 are arranged on a barge B floating in the reservoir W. The dehydrator 120 is arranged in the land part G.

The first suction tube 60</b>F has one end 20</b>A connected to the other end 20</b>B of the suction nozzle 20 and the other end 20</b>B connected to the opening 32</b>A of the housing 32 . The gap between the suction nozzle 20 and the first suction pipe 60F is sealed. The gap between the housing 32 and the first suction tube 60F is sealed. The first suction tube 60F differs from the first suction tube 60 shown in FIG. 1 in its telescopic and bendable configuration. This allows the suction nozzle 20 to move relative to the housing 32 . Although the opening 32A is arranged on the side surface of the housing 32 in FIG. 5, it may be arranged on the bottom surface of the housing 32.

The first lifting device 140 is a telescopic backhoe in the second embodiment. The first lifting device 140 has a main body 142 , a boom 144 swingable with respect to the main body 142 , and an arm 146 swingable with respect to the boom 144 and telescopic. A tip of the arm 146 is fixed to the suction nozzle 20 . The first elevating device 140 elevates and lowers the suction nozzle 20 by extending and contracting the arm 146 to insert the suction port 22 of the suction nozzle 20 into the sediment D on the bottom of the reservoir W.

The second lifting device 150 is a Teruha type hoist crane in the second embodiment. The second lifting device 150 includes a rail 152 installed above the recovery tank 40, a trolley 154 that traverses on the rail 152, a winch 156 suspended from the trolley 154, and a wire 158 that can be hoisted by the winch 156. , has A tip of the wire 158 is fixed to the housing 32 of the intermediate unit 30 . The second lifting device 150 raises and lowers the housing 32 by causing the winch 156 to wind the wire 158 and supports the housing 32 in the water of the reservoir W.

The operator positions the housing 32 of the intermediate unit 30 at a predetermined position in the water of the reservoir W by using the second lifting device 150, for example. After that, the suction port 22 of the suction nozzle 20 is inserted into the sediment D by the first lifting device 140, and the suction pump 50 and the first pressure feed pump 34 are driven to start dredging. When the sediment D around the suction port 22 is sufficiently sucked, the user operates the first lifting device 140 to change the position of the suction nozzle 20 . At this time, the position of the housing 32 is not changed.

As described above, in the dredging device 10A of the second embodiment, the first suction pipe 60F is extendable and bendable.

According to such a dredging device 10A, since the suction nozzle 20 is relatively movable with respect to the housing 32, the operability is improved, and the sediment D can be suctioned more favorably.

In the dredging device 10A, the collection tank 40 is arranged on the barge B. As shown in FIG.

According to such a dredging device 10A, the horizontal distance between the suction nozzle 20 and the collection tank 40 can be shortened, so the conveying force of the first pressure-feeding pump 34 is improved. Alternatively, a pump with a low pumping force can be used as the first pumping pump 34 .

The dredging device 10A includes a first lifting device 140 that lifts and lowers the suction nozzle 20. As shown in FIG.

According to such a dredging device 10A, the dredging device 10A can be installed more preferably. Specifically, since the suction nozzle 20 can be more preferably inserted into a predetermined position of the sediment D, it is possible to recover mud from deep water and suppress water contamination.

The dredging device 10A includes a second lifting device 150 that lifts and lowers the housing 32. As shown in FIG.

According to such a dredging device 10A, the dredging device 10A can be installed more preferably. Specifically, since the intermediate unit 30 can be more preferably positioned at a predetermined location in the reservoir W, the operability is improved, and the sediment D can be more preferably sucked.

(Modified installation example)
FIG. 6 is a schematic diagram showing a modified arrangement example of the dredging device of the second embodiment. In the dredging device 10B shown in FIG. 6, the same reference numerals are given to the same configurations as those of the dredging device 10A shown in FIG. In the dredging device 10B, the housing 32 of the intermediate unit 30 is installed on the bottom of the reservoir W. As shown in FIG. If the water depth of the reservoir W is shallow, the housing 32 can be installed on the bottom of the reservoir W. The dredging device 10B collects the heavy sediment D (earth and sand D1) by suction, and conveys the high-height earth and sand D2 by pumping, so that dredging can be efficiently performed.

(Third Embodiment)
FIG. 7 is a schematic diagram showing the dredging device of the third embodiment. In the dredging device 10C shown in FIG. 7, the same reference numerals are given to the same configurations as those of the dredging device 10A shown in FIG. The dredging device 10C includes a second lifting device 160 instead of the second lifting device 150 in the dredging device 10A. The second lifting device 160 is arranged on the barge B floating in the reservoir W.

The second lifting device 160 is a crawler crane in the third embodiment. The second lifting device 160 has a main body 162 , a boom 164 that can swing relative to the main body 162 , and a wire 166 that can be hoisted from the tip of the boom 164 . A tip of the wire 166 is fixed to the housing 32 of the intermediate unit 30 . The second lifting device 160 raises and lowers the housing 32 by winding a wire 166 to support the housing 32 in the water of the reservoir W.

10 C of dredging apparatuses can install 10 C of dredging apparatuses more suitably. Specifically, since the intermediate unit 30 can be more preferably positioned at a predetermined location in the reservoir W, the operability is improved, and the sediment D can be more preferably sucked.

Each configuration described in the embodiment may be combined with other configurations in each embodiment without departing from the scope of the invention. Moreover, each of these configurations may be combined with configurations in other embodiments that are different from each embodiment within the scope of the invention. Also, various modifications may be made without departing from the scope of the invention.

10, 10A, 10B, 10C Dredging device 20 Suction nozzle 22 Suction port 24 Injection nozzle 26 Water supply pipe 28 Protection net 30 Intermediate unit 32 Housing 34 First pressure feed pump 40 Recovery tank 42 Discharge part 50 Suction pump 60, 60F First Suction pipe 70 Second suction pipe 80 Third suction pipe 90 Pressure feed pipe 100 Lifting device 110 Second pressure feeding pump 120 Dewatering device 130 Transfer pipe 140 First lifting device 150, 160 Second lifting device 20A, 60A, 70A, 80A, 90A , 130A One end 20B, 60B, 70B, 80B, 90B, 130B Other end 32A, 32B Opening 50A Intake port 20T Cylindrical part 102, 142, 162 Main body 104, 144, 164 Boom 106, 146 Arm 152 Rail 154 Trolley 156 Winch 158 , 166 Wire W Reservoir B Barge G Land D Sedimentation D1, D2, D3 Earth and sand h1 First height h2 Second height h3 Horizontal distance

Claims (13)

a suction nozzle arranged at the bottom of the water;
a housing arranged in water;
a first pressure-feeding pump arranged inside the housing;
a first suction tube having one end connected to the suction nozzle and the other end connected to the housing;
a second suction tube, one end of which is connected to the housing and the other end of which is placed above the water;
a compressing pipe having one end connected to the first compressing pump and the other end disposed above the water;
a suction pump disposed on the water and sucking the second suction pipe;
dredging equipment. 2. The dredging device of claim 1, wherein said one end of said second suction tube is connected to the upper surface of said housing. 3. The method according to claim 1, wherein the distance from the other end of the first suction tube to the one end of the second suction tube is smaller than the distance from the other end of the first suction tube to the one end of the pumping tube. Dredging equipment as described. 4. The dredging device according to any one of claims 1 to 3, wherein the first suction pipe is extendable and bendable. 5. The dredging device according to any one of claims 1 to 4, wherein the suction nozzle comprises an injection nozzle for injecting water. The suction nozzle includes a cylindrical portion,
6. The dredging device of claim 5, wherein the injection nozzle is provided inside the tubular portion. 7. The dredging device according to any one of claims 1 to 6, wherein the suction nozzle is provided with a grid-like protective net covering the suction port. a collection tank connected to the other end of the second suction pipe and the other end of the pressure feed pipe;
8. The dredging equipment according to any one of claims 1 to 7, comprising a third suction pipe having one end connected to the recovery tank and the other end connected to the suction pump. 9. The dredging equipment of claim 8, further comprising a second pressure pump for discharging earth and sand from said collection tank. The dredging device according to claim 8 or 9, further comprising a dewatering device for dewatering earth and sand discharged from the recovery tank. 11. A dredging device as claimed in any one of claims 8 to 10, wherein the recovery tank is arranged on a barge. 12. A dredging device according to any one of claims 1 to 11, comprising a first lifting device for lifting and lowering said suction nozzle. 13. A dredging device according to any one of claims 1 to 12, comprising a second lifting device for lifting and lowering said housing.

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