KR101976773B1 - Apparatus for blocking fluid outflow in vessel accident - Google Patents

Abstract

The present invention relates to a pore blocking device for responding to a leakage of a fluid, and more particularly, to a pore blocking device for minimizing a leakage by preventing the pore of a ship from being poured into the inside of the vessel when the fluid leakage occurs.
According to the present invention, there is provided a containment device having a configuration capable of sealing a wave generated by a containment device by injecting a containment device into a tank in which an effluent material is stored, and having a configuration capable of most effectively utilizing the outflow in the tank .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a pore blocking device for a ship fluid leakage accident,

The present invention relates to a pore blocking device for responding to a leakage of a fluid, and more particularly, to a pore blocking device for minimizing a leakage by preventing the pore of a ship from being poured into the inside of the vessel when the fluid leakage occurs.

In case of leakage of oil or HNS (Hazardous and harmful material) from ship, it is necessary to quickly and thoroughly block the outflow pore in order to minimize pollution at sea. For this purpose, attempts have been made to block the outflow pores from the outside of the hull, but due to the high discharge and pressure of the outgoing material, the risk of high reactivity and explosion of the HNS is very low and the pour blocking success rate is very low, There has been a problem that the range is greatly spread.

KR 10-1001761 B1

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 an apparatus and a method for sealing a purging device by injecting a containment device into a tank storing an effluent material, The present invention provides a containment apparatus having a configuration that has a structure.

In order to achieve the above object, the present invention provides a pore blocking device for a ship fluid leakage accident, comprising: a main containment unit for sealing a piercing of a ship to prevent a fluid from flowing out; A plurality of poles radially extending from the main containment portion upon fluid input; An induction rope connected to the pole and extending radially from the main enclosure as the pole is deployed upon fluid input; And a plurality of derivatives attached to the induction rope, wherein the pole is formed to be able to be folded in a tangential direction of a surface of the main containment part for storage of the pore blocking device, Wherein the radial extension from the main containment portion of the rod is configured to be effected by the elasticity of the rod and the plurality of elastic rods are configured to extend straightly in all directions in the fluid And is configured to be sensitive to the flow of the fluid and react quickly to be led to the fluid.

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According to another aspect of the present invention, there is provided a pore blocking device for responding to a ship fluid leakage accident, comprising: a float formed to float on a fluid surface at the time of fluid input; A connecting rope connected to the bottom of the float; A plurality of main containment units attached at regular intervals along the connection rope; A plurality of poles radially extending from the respective main containment portions upon fluid input; An induction rope connected to the pole and extending radially from the main enclosure as the pole is deployed upon fluid input; And a plurality of derivatives attached to the induction rope, wherein the pole is formed to be able to be folded in a tangential direction of a surface of the main containment part for storage of the pore blocking device, Wherein the radial extension from the main containment portion of the rod is configured to be effected by the elasticity of the rod and the plurality of elastic rods are configured to extend straightly in all directions in the fluid And is configured to be sensitive to the flow of the fluid and react quickly to be led to the fluid.

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The derivative may have the shape of a cone, truncated cone, polygonal pyramid or polygonal pyramid that narrows in a radially extending direction when the rod and the guiding rope are radially deployed.

In the case of a truncated cone or polygonal prism shape, the above-mentioned derivative may have a wide bottom surface in an open form.

The derivative may be formed in a smaller volume than the main containment portion.

According to the present invention, there is provided a containment device having a structure capable of sealing a wave by a containment device by injecting a containment device into a tank storing an effluent material, and having a configuration capable of most effectively utilizing the outflow in the tank It is effective.

FIG. 1 is a conceptual view showing a state in which a pore blocking device inserted into a fluid tank prevents fluid leakage by blocking the pores of the tank.
Fig. 2 is a view showing various types of pore blocking mechanisms constituting the pore blocking device as the first embodiment, which are pushed into the fluid tank in order to block the pores of the fluid tank at the time of ship fluid outflow. Fig.
Fig. 3 is a view showing a pore blocking device as a second embodiment, which is introduced into a fluid tank to seal a pore of a fluid tank at the time of ship fluid outflow. Fig.
Fig. 4 shows a form of an embodiment of a derivative which is a component of the pore blocking device of Fig. 3; Fig.
Fig. 5 is a view showing a pore blocking device as a third embodiment, which is inserted into a fluid tank to seal a pore of a fluid tank at the time of a ship fluid leakage accident; Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

FIG. 1 is a conceptual view showing a state where a pore blocking device inserted into a fluid tank prevents a fluid outflow by blocking a pore of a tank. FIG. 2 is a schematic view showing a state in which, FIG. 3 is a view showing various types of pore blocking mechanisms to be introduced.

As shown in FIG. 1, the introduced pore blocking device moves along the flow of the fluid to the pumping portion 11 of the fluid tank, thereby closing the pumping portion 11, thereby stopping the flow of the fluid. 2 is a perspective view of a pore blocking device as a single body that is poured into a plurality of pores for blocking the piercing 11 according to various embodiments of the present invention. The pore blocking device is shown.

2 (a), 110 and 120, 'oscillating type' pore blocking mechanisms (FIGS. 2 (b) and 130), and 'revolving type' pore blocking mechanisms 2 (c), 140) are shown. Here, the names "straight type", "rotational type", and "oscillation type" are names attached to express the main characteristic when the fluid flows along the fluid flow in each form, and in each form, And a pore blocking mechanism having a form in which the features of the respective aspects of FIG. 2 are appropriately combined may also be possible as a matter of course, as a form not directly illustrated in FIG. 2, Of course, the scope of technical thought of course.

For example, the 'straight type' pore blocking mechanism can slightly exhibit the characteristics of 'swinging' when moving along the flow of fluid, and the shape characteristic of the 'straight type' pore blocking mechanism and the ' A pore blocking mechanism of a type not directly shown in FIG. 2 is also possible from the present invention, and this is also within the scope of the technical idea of the present invention. Hereinafter, the features according to each form will be individually considered.

2 (a) is a rectilinear pore blocking mechanism 110 and 120 having a concave center portion and a rectilinear front portion 111 and 121 having a density greater than that of the other portions and having a center of gravity . In other words, it has a generally flat shape, but it has a slightly concave shape at the central portion, so that it can be prevented from moving too fast in the fluid. There is a problem that when the fluid moves in the fluid excessively quickly, it may sink into the bottom of the tank before reaching the wave 11 of the fluid tank. However, the rectilinear forward portions 111 and 121 are narrowed in one direction, and the narrowed portion has a larger density than the other portions, thereby acting as a center of gravity. This is characterized in that such straight forward portions 111 and 121 are positioned forward in moving along the fluid flow and move relatively faster than other shapes while moving using lift generated in the other portion (central portion) . This enables to exhibit the effect of blocking as fast as possible (11).

2 (b) is a swinging type pore blocking mechanism 130, which has a relatively uniform density as a whole and has a concave center portion. Unlike the rectilinear pore blocking mechanisms 110 and 120 of FIG. 2 (a), since they do not have a narrow center of gravity and are weak in straightness, the center of gravity causes the flow of fluid And then proceeds toward the wave resonator 11. That is, it is difficult to reach the piercing 11 as fast as the straight piercing blocking mechanisms 110 and 120 because of the characteristic that the piercing blocking mechanism 110 gradually advances toward the piercing 11, The piercing-type pore blocking mechanism 130 has the advantage of being able to reach the piercing 11 even when it does not reach the piercing 11 by movement and sinks in the fluid tank.

2 (c) is a rotatable porthole closing mechanism 140. The rotating pawl closing mechanism 140 has a concave center portion and a rotational forward portion 141 having a density greater than that of the other portions, do. Such a rotatable pawl closing mechanism 140 has a gravity central portion narrowing in the front portion like the straight pawl blocking mechanisms 110 and 120 but unlike the straight pawl blocking mechanisms 110 and 120, But does not extend in the direction of the center, but has a rotation front portion 141 bent in a shape slightly rotating from the central portion. As a result, the flow advances in the direction of the rotation front portion 141, thereby advancing toward the wave piercing 11 while rotating in the fluid. In order to further exhibit such a rotation characteristic, the rotation front portion 141 may be formed in a shape bent on one side only in the plane, but may be bent in a slightly spiral shape if necessary. This rotating type pore blocking mechanism 140 is slower than the straight pore blocking mechanisms 110 and 120 to reach the pawl 11 but reaches the pawl 11 faster than the pawl pawl blocking mechanism 130 Can be expected to do.

The pore blocking device as the first embodiment of the present invention which is charged into the fluid tank when a fluid leakage accident occurs is characterized in that the pore blocking devices 110 and 120, the pivoting type pore blocking device 130 and the rotating pore blocking device 140 Or a pore blocking mechanism of any one type, but more preferably, a combination of two or more types of pore blocking mechanisms. This is because the straight pore blocking mechanisms 110 and 120 can be expected to have a fast pore blocking effect by progressing in a fast fluid, and the straight pore blocking mechanisms 110 and 120 can be fastened to the bottom surface of the tank It is possible to keep the pawl 11 still blocked sufficiently by the slow progress of the swinging type pawl closing mechanism 130 even if the swinging of the swinging pawl closing mechanism 130 occurs. Of course, the rotatable type pore blocking device 140 has all the advantages of the other two types, so that it can be poured together with the other two types of pores so that a better pore blocking effect can be expected.

3 is a view showing a porthole sealing device 200 as a second embodiment, which is inserted into a fluid tank to seal a pore of a fluid tank in case of a ship fluid leakage accident, and Fig. 4 is a view showing a pore sealing device 200 of Fig. 3 or Fig. FIG. 5 illustrates a form of one embodiment of the derivatives 240, 340 that is a component of the device.

The pore blocking device 200 according to the second embodiment includes a main containment part 210 that functions to seal the piercing 11 of the vessel to prevent the fluid from flowing out, A plurality of radial spreading poles 220 and an induction rope 220 connected to the pole 220 and extending radially from the main containment 210 as the rod 220 is deployed upon fluid input, a rope 230 and a plurality of derivatives 240 attached to the induction rope 230.

Fig. 3 (a) is a view showing a form in which such a pore blocking device 200 is stored. 3 (b), the rod 220 is folded in the tangential direction of the surface of the main sealing part 210 as shown in FIG. 3, As shown in Fig. That is, in order to store the folded form as shown in FIG. 3 (a), it is possible to use a mechanism such as a string which is folded in a folded form, for example. The rod 220 and the guide rope 230 connected to the rod 220 are radially arranged from the main containment unit 210 around the main containment unit 210 So that it automatically spreads out. To this end, as an embodiment, the folded portion of the pole 220 may be made of an elastic material so as to be unfolded by elasticity.

It is preferred that the pore blocking device 200 float and sink slowly at a density slightly greater than the neutral buoyancy as a whole. Neutral buoyancy means that, compared to the surrounding fluid, it has a density similar to that of the fluid. By so constituting, when the main body block 210 approaches the wave 11 in accordance with the flow of the fluid, the main body 240 spreads around without floating or sinking suddenly, The whole pore blocking device 200 including the main containment part 210 is led to the piercing 11 by being actively guided to the flow.

The derivative 240 needs to be sensitive to the effluent flow to attract the small fluid flow as well as to be actively drawn to the effluent flow to attract the pore blocking device when exposed to the effluent flow. For example, bottomed cup-shaped derivatives 240, 340, which mimic the structure of the catch structure, as shown in FIGS. 3 and 4, are aligned along the outflow when exposed to the outflow, And can actively lead the pore blocking device. 3 and 4, only the truncated cone shape is shown. However, when the pole 220 and the induction rope 230 are radially extended as shown in FIG. 3, the derivatives 240 and 340 are arranged in a radially extending direction A cone, a truncated cone, a polygonal pyramid, or a polygonal prism shape. Also, as described above, when the derivatives 240 and 340 have a truncated cone shape or a polygonal prism shape, it is preferable that the broad bottom surface has an open shape. Also, as shown in FIG. 3, the derivative 240 is formed in a smaller volume than the main containment unit 210.

The pore blocking device (200) guided by the outflow is exposed to the outflow and is actively drawn to the piercing (11). At this time, the derivative 240 may be smaller than the wave 11, and in this case, the derivative 240 can be flowed out without blocking the wave 11, but it is finally made of a material having a large size and elasticity After the wave 11 is blocked by the main containment unit 210, the remaining derivatives 240 that follow the wave guide 11 serve to seal off a part of the non-sealed portion of the wave 11.

Conventional pore blocking devices do not have the resilient pads 220 as in the present invention so that the containment mechanism and connecting ropes and derivatives 240 in the fluid are difficult to spread radially in the fluid, The time to react to the flow of the fluid was long.

However, the pore blocking device 200 according to the second embodiment of the present invention and the pore blocking device 300 according to the third embodiment to be described later with reference to FIG. 5 are formed by a plurality of elastic pads 220, So that the flow of the fluid in any direction is most sensitive to the flow of the fluid and quickly reacted to be drawn to the fluid, There are advantages to be able to.

5 is a view showing the pore blocking device 300 as the third embodiment, which is inserted into the fluid tank to block the pores of the fluid tank at the time of a ship fluid leakage accident.

The pore blocking device as the third embodiment has a float 350 formed to float on the surface of the fluid when the fluid is injected and a connecting rope 360 connected to the bottom of float 350, (Main containment portion, pole, induction rope, and derivatives) of the same configuration and configuration as those of Fig. Also, the unit pore blocking devices can be folded and stored in the form as shown in FIG. 3 (a), and the principle in which the unit pore blocking devices are spread when the fluid is supplied is also the same as FIG. 3 (b).

In other words, a plurality of main containment parts 310 attached at regular intervals along the connection ropes 360, a plurality of poles 320 radially spreading from the main containment parts 310 when the fluid is injected, An induction rope 330 in the form of a net extending radially from the main containment 310 as the rod 320 is deployed when the fluid is introduced and a guide rope 330 (Not shown).

In the pore blocking device 200 according to the second embodiment of FIG. 3, since the overall density of the main containment part 210, the rod 220, and the derivatives 240 is configured to be slightly larger than the fluid, If the study unit 11 can not be sealed, it may fall into the bottom of the fluid tank. However, in the pore blocking device 300 according to the third embodiment of FIG. 5, each of the main containment part 310, the pole 320, and the derivatives 340 is submerged by the float 350 floating on the surface of the fluid, And the containment unit is formed in multiple layers along the connection rope 360 so that the main containment unit 310 at a height closest to the wave 11 is formed at any height, It is possible to seal the wave resonator 11 more quickly by the wave resonator 11 in accordance with the fluid flow.

10: Fluid tank
11: Parsing
12: Fluid
13: fluid surface
50: Effective range
110,120: Straight-type pore blocking device
111, 121: straight forward portions (111, 121)
130: Pivoting type pore blocking mechanism
140: Rotary pawl blocking mechanism
141: rotation front portion 141,
200: Pore sealing device as the second embodiment
210: Main containment unit
220: pole
230: Induction rope
240: derivative
300: Pore sealing device as the third embodiment
310: Main containment unit
320: pole
330: Induction rope
340: derivative
350: float
360: connecting rope

Claims (10)

delete delete delete As a pore blocking device for responding to a ship fluid leakage accident,
A main containment unit which functions to seal the wave of the ship and prevent the outflow of the fluid;
A plurality of poles radially extending from the main containment portion upon fluid input;
An induction rope connected to the pole and extending radially from the main enclosure as the pole is deployed upon fluid input; And
A plurality of derivatives attached to the induction rope
Lt; / RTI >
The pole,
The main containment unit is formed to be capable of being folded in a tangential direction on the surface of the main containment unit for storage of the pore containment unit and radially expandable from the main containment unit when the fluid is supplied,
The radially extending from the main containment portion of the rod,
And is configured to be made of the above-
Wherein the plurality of elastic poles are configured to extend in four directions in the fluid so as to be sensitive to the flow of the fluid,
Pore sealing device for ship fluid spill response. As a pore blocking device for responding to a ship fluid leakage accident,
A float formed to float above the fluid surface when the fluid is loaded;
A connecting rope connected to the bottom of the float;
A plurality of main containment units attached at regular intervals along the connection rope;
A plurality of poles radially extending from the respective main containment portions upon fluid input;
An induction rope connected to the pole and extending radially from the main enclosure as the pole is deployed upon fluid input; And
A plurality of derivatives attached to the induction rope
Lt; / RTI >
The pole,
The main containment unit is formed to be capable of being folded in a tangential direction on the surface of the main containment unit for storage of the pore containment unit and radially expandable from the main containment unit when the fluid is supplied,
The radially extending from the main containment portion of the rod,
And is configured to be made of the above-
Wherein the plurality of elastic poles are configured to extend in four directions in the fluid so as to be sensitive to the flow of the fluid,
Pore sealing device for ship fluid spill response.
delete delete The method according to claim 4 or 5,
The above-
Having a cone, truncated cone, polygonal pyramid or polygonal pyramid shape narrowing in a radially extending direction when the rod and the guiding rope are radially deployed
And a pore blocking device for responding to a ship fluid leakage accident. The method of claim 8,
The above-
In the case of a truncated cone or polygonal prism shape,
And a pore blocking device for responding to a ship fluid leakage accident. The method according to claim 4 or 5,
The above-
A volume smaller than the main containment portion
And a pore blocking device for responding to a ship fluid leakage accident.

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