KR20240104365A - Device for removing microplastics of ship - Google Patents

Abstract

The present invention relates to a foreign matter removal device for ships, and to a foreign matter removal device for ships that collects and removes foreign materials contained in seawater flowing into a ship. For this purpose, there is a propulsion unit that provides propulsion for ships sailing on the sea, a seawater inlet with an opening to suck in seawater provided to the propulsion unit, and an entrance to the seawater inlet to filter out foreign substances contained in the seawater flowing in through the seawater inlet. A fixed mesh network that is fixedly placed, a structure fixed to the lower floor of a ship, is included in the seawater flowing in through the seawater inlet by moving a plurality of position-moving mesh nets with different mesh sizes in the horizontal direction according to control signals. A deformable microplastic filtering device for a ship is disclosed, which includes a mesh net position control unit for filtering foreign substances.

Description

Variable microplastic strainer for ships {DEVICE FOR REMOVING MICROPLASTICS OF SHIP}

The present invention relates to a deformable microplastic filter device for a ship, and more specifically, to a deformable microplastic filter device for a ship that captures and removes foreign substances contained in seawater flowing into the ship.

In the case of ships driven by water jets, seawater must be sucked in from the sea to generate propulsion. At this time, since seawater contains various foreign substances such as marine debris and microplastics, foreign substances contained in seawater must be sufficiently removed and supplied to the water jet propulsion unit to prevent problems in the propulsion system.

Meanwhile, in ships driven by conventional water jets, a type of mesh net of the same size is placed at the entrance of the seawater intake port that sucks in seawater, so that foreign substances of a certain size can be collected and filtered. At this time, since the mesh net placed at the seawater inlet is made of a fixed mesh net that is difficult to attach and detach, if a lot of collected foreign matter is attached to the mesh net, the suction efficiency of seawater may decrease, causing problems with the water jet propulsion. There is a problem with the inability to remove microplastics, which are a growing issue.

KR 10-2016-0008914

Therefore, the present invention was created to solve the above-mentioned problems, and its purpose is to provide an invention that can collect foreign substances contained in seawater without reducing seawater suction efficiency and even microplastics.

However, the objects of the present invention are not limited to the objects mentioned above, and other objects not mentioned will be clearly understood by those skilled in the art from the description below.

The purpose of the present invention described above is to filter foreign substances contained in seawater flowing in through a propulsion unit that provides propulsion to a ship navigating the sea, a seawater intake port formed with an opening to suck in seawater provided to the propulsion unit, and the seawater intake port. A fixed mesh net is fixedly placed at the entrance of the seawater inlet, a structure fixed to the bottom of the ship, and a plurality of movable mesh nets with different mesh sizes are moved horizontally according to control signals to open the seawater inlet. This can be achieved by providing a variable microplastic filtering device for a ship, characterized in that it includes a mesh net position control unit that filters foreign substances contained in seawater flowing through.

In addition, the mesh network position control unit,

Seawater inlet openings are formed to prevent foreign substances caught in the plurality of position-moving mesh networks from becoming stuck in the plurality of position-moving mesh networks, and seawater flowing in through the seawater inlet openings moves foreign substances attached to the plurality of position-moving mesh networks. do.

In addition, the seawater flowing in through the seawater intake opening is,

It flows in through the seawater inlet opening formed in front of the mesh network position control unit and moves toward the mesh network position control unit placed at the rear.

In addition, the plurality of positional movement mesh networks,

By alternating positions on the same virtual vertical line as the fixed mesh network according to the control signal of the mesh network position control unit, foreign substances of different sizes can be filtered out sequentially and step by step.

In addition, the mesh network position control unit,

A housing that is coupled and fixed to the lower bottom of the ship so that the seawater inlet is included inside, a seawater inlet formed on the bottom of the housing and formed on the same virtual vertical line as the seawater inlet so that the inflowing seawater is sucked back into the seawater inlet, A seawater inlet opening is formed and placed in the front of the housing so that it can be opened and closed according to a control signal. In the initial state, it is located so as not to be on the same virtual vertical line as the seawater inlet or seawater inlet, and a plurality of positioning meshes with different mesh sizes. A mesh network positioning control unit that generates a position movement control signal and drives the position movement so that any one of the net or a plurality of position movement mesh nets is on the same virtual vertical line with the seawater inlet or seawater inlet in a foreign matter removal state that is out of the initial state. Includes.

In addition, the mesh network position control unit,

A seawater intake stop signal, in which seawater is not sucked in, is transmitted from the ship's propellant control unit through the seawater inlet, and the seawater inlet opening is operated in conjunction with the input of the seawater suction stop signal to move foreign substances attached to the multiple position-moving mesh nets to the rear. Creates a moving seawater current.

In addition, it is placed at the rear of the mesh net position control unit to filter out microplastics contained in seawater flowing in through the seawater inlet or seawater inlet opening, and to filter out foreign substances contained in seawater flowing in to the rear so that only pure seawater is discharged back into the sea. It further includes a fine plastic mesh net.

In addition, the plurality of positional movement mesh networks,

They are arranged spaced apart from each other in the horizontal direction with the seawater inlet or seawater inlet in between, or spaced apart from each other in the vertical direction on one side of the seawater inlet or seawater inlet.

According to the present invention as described above, while collecting foreign substances contained in seawater, the seawater suction efficiency is not reduced, and even microplastics can be collected.

The following drawings attached to this specification illustrate a preferred embodiment of the present invention, and serve to further understand the technical idea of the present invention along with the detailed description of the invention. Therefore, the present invention is limited to the matters described in such drawings. It should not be interpreted in a limited way.
1 is a diagram schematically showing the water jet propulsion unit of a water jet propulsion ship according to an embodiment of the present invention;
Figure 2 is a diagram showing the mesh net position adjusting unit attached to the lower surface of the ship according to an embodiment of the present invention;
Figures 3 and 5 are diagrams showing a plurality of position-moving mesh networks alternately switching to collection positions according to an embodiment of the present invention;
Figures 4 and 6 are diagrams showing that the collected foreign matter according to an embodiment of the present invention is moved to the rear side of the mesh net position adjusting unit by seawater flowing in through the seawater inlet opening.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the drawings. In addition, the embodiment described below does not unduly limit the content of the present invention described in the claims, and it cannot be said that all of the configurations described in this embodiment are essential as a solution to the present invention. In addition, descriptions of matters that are obvious to those skilled in the art and skilled in the art may be omitted, and descriptions of such omitted components (methods) and functions may be sufficiently referenced without departing from the technical spirit of the present invention.

According to an embodiment of the present invention, the vessel's variable microplastic filter device is a mesh net or filter (hereinafter referred to as a mesh net) that sequentially and stepwise removes foreign substances (marine debris, microplastics) contained in seawater flowing into the ship. It is an invention that allows filtering through alternating filtering as needed by varying the size of the mesh. Hereinafter, a foreign matter removal device for a ship according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

As shown in FIG. 1, a ship 10 that obtains propulsion using a water jet generates propulsion by drawing seawater from the sea. At this time, seawater sucked from the sea is sucked through the seawater intake port 120 of the ship, and a non-detachable fixed mesh net 130 is placed at the entrance of the seawater intake port 120 to remove foreign substances contained in the sucked seawater. Filter. Seawater flowing in through the seawater inlet 120 is supplied to the propulsion unit 100 to generate propulsion. Meanwhile, the water jet described in the present invention is only an example and can include all technologies for filtering foreign substances contained in seawater flowing into a ship within the scope of the technical idea of the present invention.

As shown in FIG. 2, the mesh network position adjusting unit 200 according to an embodiment of the present invention is attached and fixed to the lower surface of the ship so that the seawater inlet 120 is included inside. The mesh network position control unit 200 alternately positions a plurality of position-moving mesh nets of different sizes provided inside on the same virtual vertical line as the seawater inlet 120, and moves the positions using the flow of seawater. Foreign substances attached to the mesh net are moved to the rear of the mesh net position control unit 200 to prevent foreign substances from being attached and fixed to the position-moving mesh net, and finally, to filter out microplastics contained in seawater and discharge only seawater back into the sea. do.

Therefore, the mesh network position adjusting unit 200 of the present invention can not only filter out foreign substances sequentially and stepwise in the vertical direction (for example, through a fixed mesh network and a plurality of position-moving mesh networks), but also in the horizontal direction. Foreign substances can be filtered out sequentially and step by step (for example, through a plurality of position-moving mesh nets and microplastic mesh nets).

For this purpose, the mesh network position control unit 200 includes a seawater inlet 201, a seawater inlet opening 202, a first position moving mesh network 211, a first mesh network driving unit 212, and a second position moving mesh network ( 221), a second mesh network driver 222, a fine plastic mesh network 231, and a mesh network position adjustment control unit (not shown).

The seawater inlet 201 according to an embodiment of the present invention is formed on the bottom surface of the body of the mesh network position adjusting unit 200 to be located on the same virtual vertical line as the seawater inlet 120. Therefore, as the water jet propulsion unit 110 is driven, the sea water flowing in through the sea water inlet 201 is sucked back into the sea water inlet 120 to generate water jet propulsion.

The seawater inlet opening 202 according to an embodiment of the present invention is disposed in front of the body of the mesh net position adjusting unit 200, and is opened and closed according to the opening and closing signal of the mesh net position adjusting control unit to allow seawater to flow in. When the mesh network positioning control unit transmits an opening/closing signal to the seawater inlet opening 202 to open and close the opening, seawater flows through the seawater inlet opening 202 due to the ship moving forward due to the water jet propulsion. ) flows into the body of the body at high speed. The seawater flowing into the mesh network position control unit 200 moves in a direction opposite to the direction of movement of the ship, and a plurality of position-moving mesh networks 211 and 221 are disposed at the rear of the seawater inlet opening 202. ) moves foreign substances attached and fixed to the rear of the mesh network position control unit 200 (i.e., toward the microplastic mesh network 231, which will be described later) to improve the filtering efficiency of the position moving mesh network.

Meanwhile, when the mesh network positioning control unit receives a seawater inflow stop signal (for example, when the water jet propulsion is not in operation) from the ship's propellant control unit (not shown in the drawing), it generates an opening/closing signal of the seawater inflow opening 202 to control the seawater flow. It is transmitted to the inlet opening (202). That is, the seawater flowing into the seawater inlet opening 202 flows in when the water jet is not in operation, and foreign substances attached to the position-moving mesh network are transported rearward and removed through the flow of the flowing seawater. However, when the water jet is operated, if necessary, an open/close signal can be generated to allow seawater to flow into the seawater inlet opening 202. However, at this time, since the water jet is in operation, the seawater flowing in through the seawater inlet opening 202 is blocked. Since the flow may not be smooth, a pump may be deployed to facilitate the movement of seawater.

As shown in Figure 2, as a first example, inside the mesh network position adjusting unit 200, a first position is arranged to be spaced apart in the horizontal direction at a certain distance with the seawater inlet 120 or the seawater inlet 201 in between. A moving mesh network 211 and a second position moving mesh network 221 are provided. Although not shown in the drawing, as a second example, a first position is placed at a certain interval in the vertical direction on one side of the seawater inlet 120 or the seawater inlet 201 (as an example, the left or right side with respect to the seawater inlet or seawater inlet). A moving mesh network 211 and a second position moving mesh network 221 may be provided.

The first positioning mesh network 211 and the second positioning mesh network 221 have different mesh sizes. Therefore, there is an advantage that the first positioning mesh network 211 and the second positioning mesh network 221 can be freely arranged alternately according to the size of foreign substances contained in seawater.

As shown in FIG. 2, the first position-moving mesh network 211 and the second position-moving mesh network 221 are in an initial state (a state other than a state in which foreign substances are removed; in this case, foreign substances are removed only by the fixed mesh network 130). Filtered), as a first example, it is arranged horizontally on both sides of the seawater inlet 120 or the seawater inlet 201, or as a second example, it is arranged vertically on one side of the seawater inlet 120 or the seawater inlet 201. It can be placed as . Hereinafter, only the first example will be described, and the same technical principles will be applied to the second example to replace the description of the first example.

On the other hand, when the first and second position movement control signals are generated by the mesh network positioning control unit, the mode is changed to a foreign matter removal state that deviates from the initial state, and at this time, the first position is moved to the first position as shown in FIG. 3 according to the first position movement control signal. The moving mesh network 211 moves to be positioned on the same vertical line as the seawater inlet 120 or the seawater inlet 201, and also moves the second position moving mesh network 221 as shown in FIG. 5 according to the second position movement control signal. ) is moved so that it is located on the same vertical line as the seawater inlet 120 or the seawater inlet 201.

According to FIGS. 3 and 5, the first positioning mesh network 211 and the second positioning mesh network 221 are connected to the seawater inlet 120 or the seawater inlet 201 by the first and second mesh network drivers 212 and 222. When selectively located on the same vertical line, foreign substances contained in seawater flowing in through the seawater inlet 201 are filtered through the position-moving mesh nets 211 and 221. Here, when the water jet is not in operation and seawater flows in through the seawater inlet opening 202 under the control of the mesh network positioning control unit, foreign substances 21 and 22 of different sizes are injected into the seawater as shown in FIGS. 4 and 6. Foreign substances attached to the mesh network can be removed by moving to the rear of the mesh network position control unit 200 due to seawater flowing in through the inlet opening 202. Therefore, it is possible to prevent the agglomeration of foreign substances collected in the mesh net and prevent the water jet suction efficiency from being reduced. Here, the first and second mesh network driving units 212 and 222 may be implemented with a motor, a conveyor belt, or a chain belt, for example.

Meanwhile, the position switching of the first position moving mesh network 211 and the second position moving mesh network 221 is difficult because too many foreign substances are collected in each mesh network, so the flow of the inhaled seawater is not smooth, so the position switching of the first position moving mesh network 211 and the second position moving mesh network 221 is difficult. Depending on whether collection switching is necessary or the size of foreign substances contained in seawater, the collection positions may be switched.

The microplastic mesh network 231 according to an embodiment of the present invention is disposed at the rearmost part of the mesh network position adjusting unit 200. It is desirable that the fine plastic mesh network 231 have the smallest mesh size so that only seawater can be discharged.

As described above, the foreign matter collection area according to an embodiment of the present invention is formed on the vertical space between the seawater inlet 120 and the seawater inlet 201, and a first position-moving mesh net 211 is installed in the foreign matter collection area. and the second position moving mesh network 221 alternately move the switching positions to collect foreign substances.

In explaining the present invention, matters that are obvious to those skilled in the art and skilled in the art may be omitted, and descriptions of such omitted components (methods) and functions may be sufficiently referenced without departing from the technical spirit of the present invention. You will be able to. In addition, the components of the present invention described above are only described for the convenience of explaining the present invention, and components not described herein may be added without departing from the technical spirit of the present invention.

The description of the configuration and function of each part described above is explained separately from each other for convenience of explanation, and if necessary, one configuration and function may be implemented by integrating with other components, or may be implemented in further detail.

Although the present invention has been described above with reference to one embodiment, the present invention is not limited to this, and various modifications and applications are possible. That is, those skilled in the art will easily understand that many modifications are possible without departing from the gist of the present invention. In addition, it should be noted that if a specific description of the known functions and their configurations related to the present invention or the combination relationship between each component of the present invention is judged to unnecessarily obscure the gist of the present invention, the detailed description has been omitted. something to do.

10: Waterjet propulsion vessel
21: First size foreign matter
22: Second size foreign matter
100: Propulsion unit
110: Water jet propulsion unit
120: Seawater inlet
130: Fixed mesh net
200: Mesh network position control unit
201: seawater inlet
202: Seawater inlet opening and closing port
211: 1st position moving mesh network
212: first mesh network driving unit
221: Second position moving mesh network
222: Second mesh network driving unit
231: Fine plastic mesh net

Claims (8)

A propulsion unit that provides propulsion to ships traveling on the sea,
A seawater intake port having an opening for sucking in seawater provided to the propulsion unit,
A fixed mesh net fixedly placed at the inlet of the seawater inlet to filter foreign substances contained in the seawater flowing in through the seawater inlet,
It is a structure fixed to the lower floor of the ship, and moves a plurality of position-moving mesh networks with different mesh sizes in the horizontal direction according to control signals to filter out foreign substances contained in seawater flowing in through the seawater intake port. A ship's variable microplastic strainer, characterized in that it includes a mesh net position control unit.
According to claim 1,
The mesh network position control unit,
Seawater inlet openings are formed to prevent foreign substances filtered by the plurality of position-moving mesh networks from becoming stuck in the plurality of position-moving mesh networks, and seawater inflowing through the seawater inlet openings is used to prevent foreign substances attached to the plurality of position-moving mesh networks. A ship's variable microplastic filter device, characterized in that it moves.
According to claim 2,
The seawater flowing in through the seawater intake opening is,
A variable microplastic filter device for a ship, characterized in that it flows in through the seawater inlet opening formed in front of the mesh net position adjusting unit and moves toward the mesh net position adjusting unit disposed at the rear.
According to claim 1,
The plurality of positional movement mesh networks are,
A variable microplastic filter net for a ship, which is capable of filtering foreign substances of different sizes sequentially and stepwise by being alternately positioned on the same virtual vertical line as the fixed mesh net according to a control signal from the mesh net position adjusting unit. Device.
According to claim 1,
The mesh network position control unit,
A housing coupled and fixed to the lower bottom surface of the ship so that the seawater intake is included inside,
A seawater inlet formed on the bottom of the housing and formed on a virtual vertical line with the seawater inlet so that the introduced seawater is sucked back into the seawater inlet,
A seawater inlet opening and closing port disposed in front of the housing to enable opening and closing according to a control signal,
In the initial state, the plurality of position-moving mesh networks are positioned so as not to be on the same virtual vertical line as the seawater inlet or seawater inlet, and have different mesh sizes;
A mesh network positioning control unit that generates a position movement control signal and drives the position movement so that any one of the plurality of position movement mesh networks is on the same virtual vertical line with the seawater inlet or seawater inlet in a foreign matter removal state that is out of the initial state. A ship's variable microplastic filter device comprising:
According to claim 5,
The mesh network position control unit,
A seawater suction stop signal in which seawater is not sucked through the seawater inlet is transmitted from the ship's propellant control unit, and the seawater inlet opening is operated in conjunction with the input of the seawater suction stop signal and attached to the plurality of position-moving mesh nets. A ship's variable microplastic strainer, characterized in that it generates a seawater flow that moves foreign substances rearward.
According to claim 5,
It is disposed at the rear of the mesh net position control unit to filter out microplastics contained in seawater flowing in through the seawater inlet or seawater inlet opening, and to filter out foreign substances contained in seawater flowing in to the rear to discharge only pure seawater back into the sea. A ship's variable microplastic filtering device further comprising a microplastic mesh net.
According to claim 5,
The plurality of positional movement mesh networks are,
A deformable microplastic filtering device for a ship, characterized in that it is arranged spaced apart from each other in the horizontal direction with the seawater inlet or seawater inlet in between, or spaced apart from each other in the vertical direction on one side of the seawater inlet or seawater inlet.