KR101455367B1 - Suction apparatus for marine deposite - Google Patents

Abstract

The present invention relates to an inhalation device for underwater sediments, which can control the direction of flow of compressed air to control the aspiration of sediments or the discharge of sediments, thereby easily preventing clogging of the aspiration duct.
The apparatus for sucking underwater sediments according to the present invention comprises: a suction pipe body having a hollow formed therein for sucking sediments in the water floor; A sleeve installed in the suction pipe body so as to be slidable along the longitudinal direction and having a through hole through which the sediment sucked through the inlet of the suction pipe body can pass; Wherein the suction pipe body has an air inlet portion in which air supplied from the air supply portion flows in front and rear directions of the air inlet portion, And the sleeve is moved forward and backward by the actuator so that the front end or the rear end of the sleeve contacts the inner surface of the first and second inclined portions to guide the moving direction of the air, do.

Description

[0001] Description [0002] Suction apparatus for marine deposits [0003]

The present invention relates to a suction apparatus for underwater sediments, and more particularly, to a suction apparatus for underwater sediments, which can control the direction of flow of compressed air to control the suction of sediments or the discharge of sediments, ≪ / RTI >

In general, sludge is accumulated on the bottom of the water such as rivers, lakes, and farms by the various soil, wastewater, or food or excrement of the farmed fish species from the land in rainy weather, or sludge is accumulated by artificial throwing. And it destroys the ecological environment. In the case of aquaculture farms, the aquaculture environment is degraded, which causes a decrease in the productivity of aquaculture.

Therefore, dredging equipment is used to remove or dredge the sludge accumulated on the bottom of rivers, lakes, and farms.

Conventional dredgers are equipped with appropriate equipment and equipment for dredging to deepen the depths of rivers, canals, harbors and routes, depending on the depth of the water area to be dredged, the type of soil on the floor, and the distance traveled by the dredged material. , Collecting soil, sand and minerals including sludge under water, foundation construction of underwater structures, and removing and removing seabed waste.

Such a conventional dredger is provided with a dredged soil suction pump at the lower end of the dredged soil suction pipe. When the suction pump is driven, sediments on the floor are dredged while being sucked into the suction pipe together with water.

In such a conventional dredger, the suction pump is installed at the end of the suction pipe so as to be locked to the bottom of the river, the river, and the reservoir, and a power line for supplying power to the suction pump must extend to the suction pump. This suction pump is installed at the end of the suction pipe and moves together with the suction pipe to suck sediment at the bottom.

Therefore, since the suction pump for sucking dredged soil is installed at the end of the suction pipe and sucks the sediment directly in the water while being moved in the water together with the suction pipe, the installation of the suction pump is not easy, In case of failure, repair was not easy.

As a method for solving such a problem, Patent Document 10-0954151 discloses a method of supplying air through an air compressor installed on a body floating on a water surface inside a vacuum suction pipe, so that supplied air moves to the upper side of a vacuum suction pipe with a weak pressure And a suction force is generated at the lower end of the vacuum suction pipe while being discharged.

However, in the above-described conventional art, when the suction pipe is clogged by the sediment in the process of sucking sediments through the suction pipe, it is difficult to remove the suction pipe quickly, which lowers the efficiency of the operation.

Registered Utility Model No. 20-0351197: Floor sludge treatment facility in river Patent Registration No. 10-0954151: Base sediment removal device and its dredging method

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a method and apparatus for controlling a moving direction of air supplied to a suction pipe to easily and quickly control suction or discharge of sediment through a suction pipe, And to provide a suction device for an underwater sediment which can improve the work efficiency.

According to an aspect of the present invention, there is provided an apparatus for sucking underwater sediments, the apparatus comprising: a suction pipe body having a hollow formed therein for sucking sediments in the water; A sleeve installed in the suction pipe body so as to be slidable along the longitudinal direction and having a through hole through which the sediment sucked through the inlet of the suction pipe body can pass; Wherein the suction pipe body has an air inlet portion in which air supplied from the air supply portion flows in front and rear directions of the air inlet portion, And the sleeve is moved forward and backward by the actuator so that the front end or the rear end of the sleeve contacts the inner surface of the first and second inclined portions to guide the moving direction of the air, do.

The suction pipe body includes a first body having an inlet for sucking sediments, a second body coupled to the rear of the first body and having an air inlet connected to the air supply unit, And the first inclined portion and the second inclined portion are respectively formed on the rear end of the first body and the front end of the third body, wherein the actuator is a pneumatic or hydraulic cylinder, and the first body The cylinder body is coupled to the outer circumferential surface of the cylinder body, and the cylinder rod drawn or drawn into the cylinder body passes through the first body and is coupled to the sleeve.

Wherein the first body is formed with a first extension portion extending from the suction port in front of the first inclined portion and the third body is formed with a second extension portion having an inner diameter corresponding to the first extension portion behind the second inclined portion, Wherein the outer diameter of the sleeve is smaller than the inner diameter of the second body and is relatively larger than the inner diameter of the first and second extensions and the length of the sleeve is such that the sleeve is spaced apart from the first ramp and the second ramp, It is preferable that the distance between the contact positions contacting the two inclined portions is relatively shorter than the distance between the contact positions.

The apparatus for sucking underwater sediments according to the present invention has an advantage in that the suction direction of the sediments can be easily performed by sucking or discharging the sediments through the suction pipe by simply adjusting the moving direction of the air flowing into the suction pipes.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view illustrating a configuration of a suction apparatus for underwater sediment according to the present invention,
FIG. 2 is an exploded perspective view illustrating the apparatus for sucking in water sediments of the present invention,
Figs. 3 and 4 are cross-sectional views of the inhalation apparatus of the underwater sediment of Fig. 2;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an apparatus for sucking underwater sediments according to the present invention will be described in detail with reference to the accompanying drawings.

The underwater sediment suction apparatus 100 of the present invention is used to suck and remove sediments accumulated on an underwater floor, such as the bottom of a river, the bottom of a river, or the bottom of a farm, as shown in FIG.

A suction pipe (20) extends from the float (10) floated on the water surface, and a suction pipe body (110) is provided on the suction pipe (20). The compressed air is supplied to the suction pipe body 110 through the air supply part 170 provided in the float 10 to generate a suction force for sucking the sediment from the suction pipe body 110.

2 to 4, the apparatus 100 for sucking underwater sediments according to the present invention includes a suction pipe 110, a sleeve 150 movably installed on the suction pipe 110, And an air supply unit 170 for supplying compressed air to the suction pipe body 110. The air supply unit 170 includes an air supply unit 170,

The suction pipe body 110 is a hollow body having a hollow extending along the longitudinal direction so that the sediment can be sucked and passed therethrough. The first body 111, the second body 120, and the third body 130 are coupled to each other Respectively.

The first body 111 is formed with a suction port 112 through which a sediment is sucked at a front end thereof and includes a first extension part 113 extending a predetermined length rearward from the suction port 112, And a first inclined portion 114 whose inner diameter gradually increases as it extends rearward from the rear end of the first inclined portion 114.

A through hole 115 is formed in the first inclined portion 114 so as to pass from the outer circumferential surface to the inner circumferential surface and the through hole 115 is formed to allow the cylinder rod 162 of the actuator 160, will be.

The second body 120 is coupled to the rear end of the first body 111 and is formed in a cylindrical shape corresponding to the diameter of the rear end of the first body 111, An air inlet 121 is formed so that air can be introduced.

The third body 130 is coupled to a rear end of the second body 120 and is connected to the second body 120. The front end of the third body 130 has a second inclined portion 132 whose inner diameter gradually decreases from the front end toward the rear, And a second extension part 131 extending a predetermined length rearward from the end of the second slope part 132. The suction pipe 20 is connected to the rear end of the second extension part 131, do.

The first extending portion 113 and the second extending portion 131 are formed in a cylindrical shape with no change in inner diameter and the first extending portion 113 and the second extending portion 131 have the same inner diameters .

A flange 140 is formed at the rear end of the first body 111 and at both ends of the second body 120 and at the front end of the third body 130 so that the flange 140 is engaged. A flange 140 for fastening the suction pipe 20 is formed at the rear end of the third body 130.

The sleeve 150 is formed to be movable forward and backward along the longitudinal direction of the suction pipe 110 by a predetermined distance. The sleeve 150 is hollow and has a hollow shape to allow the sediment that is sucked through the suction port 112 to pass therethrough. It is a hollow body.

The inner diameter of the sleeve 150 is formed to correspond to the inner diameter of the first extending portion 113 and the second extending portion 131. The outer diameter of the sleeve 150 is larger than the inner diameter of the first and second extending portions 131, The inner diameter of the second body 120 and the rear end of the first inclined portion 114 and the front end of the second inclined portion 132 are relatively small. The length of the sleeve 150 is set such that the length of the sleeve 150 is equal to the length of one side of the first inclined section corresponding to the outer diameter of the sleeve 150 and the length of the second inclined section corresponding to the outer diameter of the sleeve 150, And is formed to be relatively shorter than the distance between one side of the slope section.

The sleeve 150 is provided with two fixing bars 151 projecting outward on the outer circumferential surface of the fixing bar 151 so as to be spaced along the longitudinal direction of the fixing bar 151. The cylinder rod 162 of the actuator 160, do.

The actuator 160 is for driving the sleeve 150 to advance and retreat, and a pneumatic cylinder or a hydraulic cylinder is used. In this embodiment, a pneumatic cylinder is applied. The cylinder body 161 is provided with the cylinder body 161 in the first body 111, extends from the cylinder body 161, and is drawn out and drawn into the cylinder body 161 The cylinder rod 162 is inserted into the suction pipe body 110 through the through hole 115 of the first body 111 and is fastened to the fixing bar 151 of the sleeve 150. When the cylinder rod 162 is pulled into the cylinder body 161 by the pneumatic pressure, the sleeve 150 moves to the front side of the intake pipe 110. On the contrary, when the cylinder rod 162 moves from the cylinder body 161 The sleeve 150 is moved to the rear of the suction pipe body 110. As shown in FIG.

The air supply unit 170 supplies air to the suction pipe body 110 to form a suction force. The air supply unit 170 is installed in the float 10 floating on the water surface as described above, and a commonly used compressor is applied.

The driving process of the inhalation apparatus 100 for underwater sediment according to the present invention having the above-described structure will be described as follows.

When the sediment is driven to be sucked through the suction pipe body 110, the suction port 112 is positioned toward the sediment to be sucked through the suction pipe body 110 and then the compressed air is supplied to the suction pipe body 110 through the air supply part 170 . At this time, the sleeve 150 inside the suction pipe body 110 is advanced forward so that the front end thereof contacts the inner surface of the first slope part 114, and the compressed air introduced into the suction pipe body 110 flows into the sleeve 150 and the second inclined portion 132 and moves in the direction of passing through the second body 120 and moves at a high speed between the sleeve 150 and the second body 120 The pressure of the rear side of the sleeve 150 is lowered by the air, and the suction of the sediment through the suction port 112 is performed. The compressed air continuously supplied passes through the suction pipe 20 through the gap between the sleeve 150 and the second inclined portion 132 to generate a suction force at the inlet of the suction pipe body 110 and moves the suctioned sediment upward So as to move.

However, when sediment having a large length or a large outer diameter flows into the suction pipe body 110 and the suction port 112 or the pipe becomes clogged, the compressed air is blown forward to discharge the sediment trapped in the suction pipe body 110 from the suction pipe body 110 Solves the clogging of the pipeline. The actuator 160 is driven so that the cylinder rod 162 is drawn out from the cylinder body 161 and the sleeve 150 connected to the cylinder rod 162 moves together with the cylinder rod 162 And retreats toward the third body 130 side. When the sleeve 150 is retracted, the rear end of the sleeve 150 contacts the inner surface of the second inclined portion 132, and the flow path of the compressed air moving backward of the sleeve 150 is blocked, The compressed air that has flowed into the second body 120 through the space between the front ends of the sleeves 150 is advanced so that the compressed air is discharged toward the inlet 112 through the first body 111 The sediment hanging from the first body 111 is discharged to the suction port 112 side while moving to eliminate clogging of the suction pipe body 110. When the inside of the suction pipe body 110 is pierced, the sleeve 150 is advanced back to the first body 111 side through the actuator 160 to generate a suction force so as to suck the deposit, and the suction operation is continued.

As described above, the inhalation apparatus 100 for underwater sediments according to the present invention has a simple structure for controlling the suction or discharge direction of sediments, so that a simple and efficient suction operation can be performed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10; Float 20; Suction pipe
100; Suction device of underwater sediment
110; Suction pipe body
111; A first body 112; Inlet
113; A first extension 114; The first inclined portion
115; Through hole 120; Second body
121; Air inlet 130; Third body
131; A second extension 132; The second inclined portion
140; flange
150; sleeve
151; Fixed bar
160; Actuator
161; Cylinder body 162; Cylinder rod
170; Air supply portion

Claims (4)

A suction pipe body having a hollow formed therein for sucking sediments of the underwater floor;
A sleeve slidably installed along the longitudinal direction inside the suction pipe body and having a through hole formed therein for allowing the sediment sucked through the inlet of the suction pipe body to pass therethrough;
An actuator installed in the suction pipe body for driving the sleeve to move forward and backward;
And an air supply unit for supplying compressed air to the suction pipe body,
The suction pipe body is formed with first and second inclined portions formed so as to have an inner diameter gradually smaller toward the front and the rear than the air inlet portion into which the air supplied from the air supply portion flows, Wherein a front end or a rear end of each of the first and second sloping portions is in contact with an inner surface of the first and second sloping portions so as to guide the moving direction of the air while being advanced or retracted by the actuator. The method according to claim 1,
Wherein the suction pipe includes a first body having a suction port for sucking sediments therein, a second body coupled to the rear of the first body and having an air inlet connected to the air supply unit, And a second body coupled to the second body,
Wherein the first inclined portion and the second inclined portion are respectively formed on the rear end of the first body and the front end of the third body. 3. The method of claim 2,
Wherein the cylinder is a pneumatic or hydraulic cylinder and the cylinder body is coupled to the outer circumferential surface of the first body and the cylinder rod drawn or drawn into the cylinder body passes through the first body and is coupled to the sleeve Characterized in that the suction device of the underwater sediment. 3. The method of claim 2,
Wherein the first body is formed with a first extension portion extending from the suction port in front of the first inclined portion and the third body is formed with a second extension portion having an inner diameter corresponding to the first extension portion behind the second inclined portion, Lt; / RTI >
Wherein the outer diameter of the sleeve is smaller than the inner diameter of the second body and is relatively larger than the inner diameter of the first and second extensions and the length of the sleeve is such that the sleeve contacts the first ramp and the second ramp, And is formed to be relatively shorter than the distance between the contact positions to be brought into contact with each other.

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