KR101339890B1 - Complex dredger and dredging method using the same - Google Patents

Abstract

The present invention relates to a composite dredger and a dredging method using the same, and more specifically, the swing operation of the fork lane for dredging is made smoothly, and at the same time, the structure of the dredged soil and other various sludges can be easily improved and newly improved. In addition, the present invention relates to a composite dredger and a dredging method using the same to make dredging work more stable and convenient.
That is, the present invention is equipped with a gravure bucket for the excavation on the boom of the fork lane mounted on the buoyancy boat (barge) of the dredger, hopper and pumping that can directly process the sludge and dredging excavated by the gravure bucket Based on the installation of the equipment directly on the upper side of the buoyancy vessel, the dredger's forkrain is designed to prevent twisting or bending of the vacuum suction hose when the boom swings, and to support foreign substances on the underwater bottom. It is intended to provide a hood structure having a water jet capable of vacuum suction, a new dredger structure having a gear operation structure added to a spud capable of fixing a barge at a desired position, and a dredging method using the same.

Description

Complex dredger and dredging method using the same

The present invention relates to a composite dredger and a dredging method using the same, and more specifically, the swing operation of the fork lane for dredging is made smoothly, and at the same time, the structure of the dredged soil and other various sludges can be easily improved and newly improved. In addition, the present invention relates to a composite dredger and a dredging method using the same to make dredging work more stable and convenient.

In general, sludge is deposited on the bottom of the surface of rivers or lakes by various wastewater flowing from the land during rainy weather, or sludge is accumulated by artificial throwing. These sludges accelerate the water pollution and destroy the ecological environment. It is the cause.

Therefore, a dredger is used to remove and dredge sludge accumulated on the bottom surface of a river or a lake.

The dredger is dredged to deepen the depth of rivers, canals, ports, and routes by mounting appropriate equipment and equipment according to the depth of the dredged water, the type of soil at the bottom, and the transport distance of dredged materials. It is used to collect soil, sand and minerals, including sludge under water, to build underwater structures, and to lift and remove sea waste.

Conventional dredgers have a type in which a fork lane including a bucket is mounted on a buoyancy vessel, and a dredged soil suction pipe and a hose for suctioning sludge including dredged soil are connected to a bucket portion connected to the boom of the fork lane.

First, when the dredging operation such as the bucket of the forklane pumps the contaminated sediment deposited on the bottom of the river or reservoir using the conventional dredging, dredged soil and hoses through the dredged soil suction pipe and hose mounted on the bucket portion of the forklane When the sludge is sucked in, the dredge soil suction pipe and the hose is twisted when the boom of the fork lane is operated in the left and right direction and the vertical direction.

That is, when the forklane boom of the dredger swings, the kink or bending of the dredged soil suction pipe and the suction hose connected thereto occurs, which hinders the dredging work of the forklane.

Second, when dredging the contaminated sediments deposited on the bottom of rivers or reservoirs using conventional dredging, dredgers are floating due to the flow of water, leaving the dredging work position, or shaking from side to side during dredging work. In order to prevent the phenomenon, the dredger could be fixed vertically and fixed at the dredging position by using hydraulic force, so that the dredger could be fixed so as not to shake. When water penetrated the hydraulic power supply means at the time, there was inconvenience in operation due to frequent failures.

Third, when dredging the contaminated sediments deposited on the bottom of rivers or reservoirs using conventional dredging, if the foreign body of the underwater bottom is formed thick, the sedimented foreign material is not properly removed, and eventually accumulated in the lower layer of the foreign material There was a disadvantage that dredging work of dredged soil was not done smoothly.

The present invention has been devised in view of the above, it is equipped with a gravure bucket for the excavation on the boom of the fork lane mounted on the buoyancy ship (barge) of the dredger, and directly excavated sludge and dredged soil by the gravure bucket It is based on the installation of hopper and pumping equipment that can be injected and processed on the upper surface of buoyancy vessel, and it is structured to prevent twisting or bending of vacuum suction hose when the boom of dredger's fork lane swings. And a complex dredger with a hood structure having a water jet capable of supporting a foreign substance in the water bottom and vacuum suction, and a gear operation structure added to a spud which can fix a barge at a desired position, and a dredging method using the same. The purpose is to provide.

According to an aspect of the present invention, there is provided a dredger including a fork lane mounted on a buoyancy vessel, the grab bucket being detachably mounted to a boom of the fork lane to excavate sludge and dredged soil; A hood device having a water jet that is mounted on the boom of the fork-lane and replaceable with a grab bucket to support a foreign material on the bottom of the water to vacuum suction; A hopper mounted at a predetermined position on the upper surface of the buoyancy vessel so as to directly inject the sludge and dredged soil excavated from the grab bucket; A pumping facility installed at an upper surface of the buoyancy vessel adjacent to the hopper to pump and transport the sludge and dredged soil introduced into the hopper to a desired place; A twist prevention means mounted at a connection point between the hood device having the water jet and the vacuum suction hose extending to the pumping facility, so that the vacuum suction hose is not twisted during the swing movement of the boom; A spud elevating device of a gear drive type mounted to elevate and unload the spud on the rear end of the buoyancy vessel; Provides a composite dredger, characterized in that configured to include.

A hood apparatus having the water jet according to the present invention includes: a hood mounted to a boom of a fork lane; A water jet pressure supply pipe mounted on an upper surface of the hood; A water jet nozzle connected to the water jet pressure supply pipe and mounted to both bottom surfaces of the hood; A vacuum suction tube mounted at a predetermined bottom surface of the hood; A vacuum suction hose connected between the vacuum suction pipe and the pumping facility; .

Preferably, the bottom edge of the hood is characterized in that a plurality of position fixing support rods are supported integrally attached to the bottom of the water.

The anti-twist means according to the present invention comprises: connecting the upper surface of the hood of the hood device with a water jet and the vacuum suction hose extending to the pumping facility with a single pipe, the bearing for rotation during the swing movement of the boom to the connection point of the pipe It is characterized in that the mounting.

The gear-driven spud elevating device according to the present invention includes: a spud elevating passage body mounted on both rear sides of a buoyancy vessel; A rack mounted along the longitudinal direction on the inner surface of the spud; A drive motor mounted at an upper surface position of the buoyancy vessel adjacent to the spud elevating passage; A drive gear mounted to the output shaft of the drive motor and engaged with the rack; .

The dredging method using a composite dredger of the present invention for achieving the above object comprises: replacing and assembling a hood having a vacuum jet pipe connected to a water jet nozzle and a vacuum suction hose at the boom end of a fork lane mounted on a dredger; Fixing the hood so that the position fixing support rod of the hood mounted on the end of the boom is stuck to the bottom of the water; Spraying the high pressure water jet supplied through the water jet pressure supply pipe from the water jet nozzle of the hood to the underwater bottom surface; Removing foreign matter accumulated on the bottom of the water by the high pressure water jet sprayed from the water jet nozzle and lifting the water onto the water surface; A vacuum is applied to the vacuum suction tube of the hood so that foreign matters suspended from the bottom of the water are vacuum suctioned; A vacuum suctioned foreign matter is transported along the vacuum suction hose to the pumping facility, and then pumped and accumulated to a predetermined position on the land by the pumping operation of the pumping facility; It characterized in that proceeds to.

Through the above-mentioned means for solving the problems, the present invention provides the following effects.

According to the present invention, by excavating sludge and dredging in the water into the gravure bucket in the usual hopper directly, the sludge and dredged soil introduced into the hopper is pumped to the desired land site in the pumping device can be easily dredging operation.

In particular, by attaching a hood device having a water jet to the boom of the fork-lane, by blowing the foreign matter thickly accumulated on the bottom of the water with the water jet to support and vacuum suction, it is possible to easily remove the foreign matter deposited on the bottom of the water.

In addition, when operating the boom of the fork lane in the left and right and up and down direction during dredging work, the end pipe of the twist prevention means rotates around the bearing, thereby preventing the kink phenomenon of the vacuum suction hose that sucks the dredged soil. The interference phenomenon between the vacuum suction hoses can be prevented.

In addition, although the conventional hydraulic mechanism is used to raise and lower the spud, in the present invention, by simply raising and lowering the spud by the rack and gear driving method, it is possible to reduce the manufacturing cost compared to the conventional hydraulic method. .

1 and 2 are perspective views showing a composite dredger according to the present invention,
3a and 3b is a perspective view showing a hood device having a water jet of a composite dredger according to the present invention,
4 is a cross-sectional view illustrating the vacuum suction hose twist prevention means of the composite dredger according to the present invention;
Figure 5 is a perspective view showing a spud hoisting device of the gear drive system of a composite dredger according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, the dredger should be fixed at a predetermined position in a river or the like for dredging work of the dredging complex, and for this purpose, as shown in FIGS. 1 and 2, the dredger is fixed to both sides of the rear end of the buoyancy vessel 10. A gear drive type spud elevating device 40 is provided as a means for elevating the spud 42 for lifting.

The gear-driven spud elevating device 40 moves the rack and the gear so that the spud 42 can be lifted and lowered by the gear-driven method, instead of lifting and lowering the spud by the expensive hydraulic drive system. It is simply configured.

As shown in FIG. 5, a hollow spud elevating passage 41 serving as a guide path for raising and lowering the spud 42 in one configuration of the spud elevating device 40 is provided. The rear end of the buoyancy boat 10 is integrally mounted on both sides.

In this case, the rack 43 is integrally mounted on the inner surface of the spud 42 along the longitudinal direction, and the rack 43 is exposed through the rear cutout of the spud elevating passage 41. do.

As another configuration of the spud elevating device 40, the drive motor 44 is mounted on the upper surface position of the buoyancy vessel 10 adjacent to the spud elevating passage 41, the drive motor 44 A drive gear 45 that engages the rack 43 is connected to the output shaft.

That is, the drive gear 45 connected to the output shaft of the drive motor 44 is engaged with the rack 43 of the spud 42 exposed through the rear end cutout of the spud elevating passage 41. .

Accordingly, the drive gear 45 is rotated at the same time as the drive motor 44 is rotated, and the rotational force at this time is transmitted to the rack 43 meshed with the drive gear 45, thereby having a rack having the rack 43. As the pod 42 descends and the lower end thereof is supported on the bottom of the water, the buoyancy boat 10 of the dredger is fixed to a desired position, and the dredging operation is performed in such a state.

Of course, in the case of moving to another place after dredging work, by driving the drive motor 44 back to the drive gear 45 and the rack 43, the lifting motion of the spud 42 again.

At the end of the boom 12 of the fork lane 11 mounted on the buoyancy boat 10, barge of the dredger according to the present invention is equipped with a gravure bucket 13 for picking up the sludge or dredged soil, the rear buoyancy of the fork lane 11 On the upper surface of the ship 10, a hopper 14 for introducing dredged soil and a pumping facility 15 for pumping and transporting dredged soil and the like introduced into the hopper 14 to a predetermined position on land are arranged side by side.

Therefore, the dredging operation is performed in the state in which the buoyancy vessel 10 of the dredger is fixed to the desired position by the spud 42, and the gravure bucket 13 moves the boom 12 of the fork lane 11 at the same time. Excavation is carried out by picking up the sludge and dredged soil), and the dredged soil, which is subsequently excavated with the grab bucket 13, is directly injected into the hopper 14 mounted on the buoyancy vessel 10, and the hopper 14 Dredged soil, etc. introduced into the pumping facility 15 is pumped up to the predetermined position of the land by the pumping operation at the same time is stacked.

On the other hand, by using the grab bucket 13 to dredge the sludge and dredging soil directly into the hopper 14, when the foreign matter is formed thick in the bottom of the water, rather than causing the dredging operation, foreign matters Kicking should be done first.

To this end, the grab bucket 13 according to the present invention is removed from the boom stand 12 of the fork lane 11, and then a hood device having a water jet is mounted on the end of the boom stand 12, and a thick foreign material layer formed on the bottom of the water. A high pressure water jet or air jet is sprayed on to support the foreign matter.

3A and 3B, the hood device 20 having the water jet is mounted on the boom 12 of the fork lane 11 so as to be interchangeable with the grab bucket 13, As a device for supporting a foreign matter and vacuum suctioning of the supported foreign matter, the hood 21 mounted on the boom 12 of the fork lane 11 is used as a skeleton.

In addition, a water jet pressure supply pipe 22 connected to the water jet supply means is mounted on an upper surface of the hood 21, and a high pressure water jet is connected to both sides of the water jet pressure supply pipe 22 on both bottom surfaces of the hood 21. A plurality of water jet nozzles 23 for spraying the water are mounted.

In addition, a predetermined position on the bottom surface of the hood 21 is equipped with a vacuum suction tube 24 for sucking foreign matters, etc. suspended from the bottom of the water by the injection force of the water jet nozzle 23, the vacuum suction tube 24, the pumping equipment A vacuum suction hose 25 extending up to 15 is connected.

At this time, the lower edge of the hood 21, when spraying the water jet, a plurality of position fixing support rods 26 are supported by being held on the bottom surface of the water so as to fix the hood 21 to the bottom of the water integrally Attached.

Looking at the operation flow of the hood device 20 having the above water jet as follows.

First, move the boom 12 to position the hood 21 at the desired underwater bottom position, and the hood 21 is fixed so that the position fixing support rod 26 of the hood 21 is fixed to the underwater bottom. .

Subsequently, when the high pressure water jet is supplied through the water jet pressure supply pipe 22, the high pressure water jet is injected from the water jet nozzle 23 onto the underwater bottom surface in which the foreign matter is thickly formed.

As a result, the foreign matter accumulated on the bottom of the water is removed by the high pressure water jet sprayed from the water jet nozzle 23 and is easily supported above the water surface.

At the same time, when the vacuum acts on the vacuum suction tube 24 by the operation of the vacuum suction means (not shown), foreign matters, etc., floated from the bottom of the water by the injection force of the water jet nozzle 23 are vacuum suction tube 24. The vacuum sucked through, and the foreign matter sucked in the vacuum is transferred to the pumping facility 15 along the vacuum suction hose 25, and is then pumped and accumulated to a predetermined position on the land by the pumping operation of the pumping facility 15.

Here, when the boom 12 of the dredger's fork lane 11 swings, a phenomenon in which the vacuum suction hose 25 is twisted or folded occurs, and the boom 12 touches the vacuum suction hose 25 and interferes with the phenomenon. In order to prevent this, in the present invention, the vacuum suction hose 25 during the swing movement of the boom 12 at the connection point between the hood 21 of the hood device 20 having the water jet and the vacuum suction hose 25. The twist prevention means 30 is installed to prevent the twist.

More specifically, as shown in FIG. 4, the anti-twist means 30 includes a vacuum suction hose 25 extending to the top surface of the hood 21 of the hood device 20 having a water jet and to the pumping facility 15. It consists of a single pipe 31 connected to each other, and a pair of bearings 32 for rotation of the single pipe 31.

At this time, the bearing 32 is mounted at the connection point between one end of the end pipe 31 and the flange of the upper surface of the hood 21, and also the connection point between the other end of the end pipe 31 and the flange connected to the vacuum suction hose 25 Is mounted on.

Therefore, when the boom 12 of the fork lane 11 of the dredger swings in the vertical and horizontal directions, the vacuum suction hose 25 is moved by the sliding action of the bearing 32 located at both ends of the end pipe 31. Since the rotation is 360 degrees, it is possible to prevent the interference phenomenon between the boom 12 and the vacuum suction hose 25, and also to easily prevent the phenomenon of twisting or bending the vacuum suction hose 25.

10: buoyant ship 11: forkrain
12: boom 13: gravure bucket
14 hopper 15 pumping equipment
20: hood device having a water jet 21: hood
22: water jet pressure supply pipe 23: water jet nozzle
24: vacuum suction tube 25: vacuum suction hose
26: position fixing support rod 30: twist prevention means
31: single tube 32: bearing
40: spud elevating device 41: spud elevating passage
42: Stud 43: Rack
44: drive motor 45: drive gear

Claims (6)

In the dredger including the fork lane 11 mounted on the buoyancy boat 10,
A grab bucket 13 mounted detachably at the end of the boom 12 of the fork lane 11 to excavate sludge and dredged soil;
A hood device 20 mounted on the boom 12 of the fork lane 11 so as to be replaceable with the grab bucket 13, and having a water jet for supporting a foreign substance in the underwater bottom and vacuum suction;
A hopper 14 mounted at a predetermined position on an upper surface of the buoyancy vessel 10 so as to directly inject the sludge and dredged soil excavated from the grab bucket 13;
A pumping facility (15) installed at an upper surface of the buoyancy vessel (10) adjacent to the hopper (14) to pump and transport the sludge and dredged soil introduced into the hopper (14) to a desired place;
Mounted at the connection point between the hood device 20 having the water jet and the vacuum suction hose extending to the pumping equipment 15, the twisting of the vacuum suction hose 25 is not twisted during the swing movement of the boom 12 Prevention means (30);
A spud elevating device (40) of a gear drive type mounted to raise and lower the spud (42) at the rear end of the buoyancy vessel (10);
Complex dredger, characterized in that configured to include.
The method according to claim 1,
The hood device 20 having the water jet is:
A hood 21 mounted to the boom 12 of the fork lane 11;
A water jet pressure supply pipe 22 mounted on an upper surface of the hood 21;
A plurality of water jet nozzles 23 connected to the water jet pressure supply pipe 22 and mounted to both bottom surfaces of the hood 21;
A vacuum suction pipe 24 mounted at a predetermined position on the bottom surface of the hood 21;
A vacuum suction hose 25 connected between the vacuum suction pipe 24 and the pumping facility 15;
Composite dredger, characterized in that consisting of.
The method according to claim 2,
Composite dredger, characterized in that the lower edge of the hood 21 is integrally attached to a plurality of position fixing support rods 26 are supported by the bottom of the water.
The method according to claim 1,
The twist prevention means 30 is:
Connect the upper surface of the hood 21 of the hood device 20 having the water jet and the vacuum suction hose 25 extending to the pumping facility 15 with a short pipe 31 and a boom at the connection point of the short pipe 31. Composite dredger, characterized in that the mounting of the bearing 32 for rotation during the swing movement of (12).
The method according to claim 1,
The gear drive type spud elevating device 40 is:
A spud elevating passage 41 mounted on both rear ends of the buoyancy vessel 10;
A rack 43 mounted along the longitudinal direction on the inner surface of the spud 42;
A drive motor 44 mounted at an upper surface position of the buoyancy vessel 10 adjacent to the spud elevating passage 41;
A drive gear 45 mounted to the output shaft of the drive motor 44 and engaged with the rack 43;
Composite dredger, characterized in that consisting of.
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