KR102134370B1 - Diffusion Device of Outboard Discharge Water - Google Patents

Abstract

The present invention provides an apparatus for spreading outboard discharge water, which is installed in an outlet end of a discharge pipe discharging seawater used for purifying exhaust gas in a sulfur oxide reducing device provided in a ship to the outside of the ship. The apparatus for spreading outboard discharge water includes: a plurality of first wing plates installed in the outlet end of the discharge pipe in a horizontal direction; and a plurality of second wing plates installed in the outlet end of the discharge pipe in a vertical direction, wherein the first wing plates and the second wing plates allow a portion orthogonal to each other to be connected by welding so that a structure in a grid shape is formed. Each of the first wing plates and the second wing plates is installed to be inclined toward an outer direction of the discharge pipe based on a central shaft of the discharge pipe so that the spread of the seawater discharged through the discharge pipe is induced.

Description

Diffusion Device of Outboard Discharge Water}

The present invention relates to a diffusion device for outboard effluent, and more specifically, by rapidly diluting the acidic pH of the effluent by diffusing the effluent in the process of discharging the effluent discharged from the scrubber that processes the exhaust gas of the ship, It relates to an outboard effluent diffusion device that makes it possible to satisfy the IMO regulations for outboard effluent.

The problem of air pollution and global warming due to the increase in the use of fossil fuels due to the rapid progress of industrialization is getting serious. As one of the main causes of such air pollution, sulfur oxides (SOx) and nitrogen oxides (NOx) contained in exhaust gas generated from ships or offshore plants are among the best. Emission regulations are being introduced.

Among the exhaust gases emitted from ships, sulfur oxides and nitrogen oxides are representative air pollutants that are regulated by the International Maritime Organization (IMO). In particular, sulfur oxides have been released from January 1, 2010 as SECA (Sulfur Emission Control Area) is regulated to 0.1% or less, and from January 1, 2020, emissions from all global seas are regulated to 0.5% or less.

In order to meet these emission regulations, various facilities have been applied to various types of combustion facilities provided on ships to treat exhaust gas including sulfur oxides and particulate matter.

A representative sulfur oxide reduction device among exhaust gas treatment devices includes a scrubber that removes sulfur oxides by spraying a basic solution such as sea water or sodium hydroxide (NaOH) to the exhaust gas.

In general, the scrubber may be divided into an open loop type, a closed loop type, and a hybrid loop type.

The open-loop type scrubber removes (or neutralizes) sulfur oxides in the exhaust gas by directly spraying seawater onto the scrubber and then uses the alkaline component contained in the seawater, and then discharges the used seawater to the outside of the ship.

The open-loop type scrubber has the advantage of being the simplest and the least expensive to operate, but it has the disadvantage that it is not applicable in areas with strong regulations related to seawater discharge because it discharges the used seawater.

The closed-loop scrubber removes sulfur oxides from the exhaust gas by spraying a scrubber with washing water containing additives such as sodium hydroxide (NaOH). At this time, the washing water is not discharged out of the ship, and is continuously circulated in the ship through the circulating water tank, and when the ship docks at the port, waste and wastewater are treated on the ground.

Unlike open-loop type scrubbers, closed-loop scrubbers can be applied regardless of local regulations, but since scrubbing water must be continuously circulated in the vessel, salts of sulfur oxides may accumulate and scale may occur. There is a need for various devices and tanks to circulate the washing water, which results in spatial constraints.

The hybrid-type scrubber may adopt the advantages of the open-loop type and the closed-loop type, respectively, but the system is complicated, so installation and operation costs are increased, and like the closed-loop type, there are disadvantages of spatial constraints.

Therefore, the existing ship has preferred the open-loop type scrubber because it is difficult to secure the installation space of the scrubber due to the internal space limitation.

1 is a view schematically showing an exhaust gas treatment system to which an open-loop type scrubber is applied.

Referring to FIG. 1, the seawater supplied by the seawater pump 10 is injected into the open-loop scrubber 20 and the exhaust gas from which sulfur oxides are removed by the alkaline component of the seawater inside the scrubber 20 is Discharged through the gas discharge line GL connected to the upper end of the scrubber 20, and the seawater used for purification of the exhaust gas in the scrubber 20 ships through the seawater discharge line WL connected to the lower end of the scrubber 20. Is discharged to the outside.

In addition, by the monitoring system 30, the content of sulfur oxides or carbon dioxide contained in the gas discharged through the gas discharge line GL, and the pH of the seawater discharged through the seawater discharge line WL (discharged water) And temperature can be monitored from time to time.

On the other hand, according to the regulations of the IMO, the discharged water discharged from the ship must satisfy a pH of 6.5 or more at a point 4 m away from the hull.

Normally, the pH of seawater before reacting with the scrubber is mostly 8 or higher, but since the pH of seawater after reaction in the scrubber is mostly lowered to 4 or less, efforts to satisfy the above regulations are required.

Conventionally, in order to satisfy the IMO regulations, a method of diluting seawater (exhausted water) discharged after being used in a scrubber by mixing it with fresh water having a higher pH before discharging it is also used.

However, the conventional method further includes a process of diluting the effluent before outboard discharge, which is inefficient, and has a disadvantage in that the system is complicated because a line and a mixing tank for supplying fresh water are further required for dilution of the effluent.

Republic of Korea Patent Publication No. 10-2014-0087782 (2014.07.09 published)

The technical problem to be achieved by the present invention is to reduce the risk to marine organisms caused by acidic effluent by rapidly dispersing the effluent in the process of discharging the seawater discharged after being used in the scrubber, and also regulate the regulatory standards prescribed by IMO. It is to provide a device for distributing off-board effluents that can be satisfied.

In addition, the present invention does not include a separate process of diluting the discharged water in solving the above problems, and satisfies the IMO regulation standard by simply installing a diffusion device in a pipe through which the discharged water is discharged from a scrubber. I want to make it possible.

In order to achieve the above object, the present invention is an outboard discharge water diffusion device installed at the outlet end of the discharge pipe for discharging seawater used for purification of exhaust gas to the outside of the ship, horizontal to the outlet end of the discharge pipe A plurality of first wing plates installed in a direction; And a plurality of second wing plates installed vertically at the outlet end of the discharge pipe, wherein the first wing plates and the second wing plates are connected to each other by orthogonal parts by welding to grid. Forming a structure of the form, each of the first wing plate and the second wing plate is installed inclined toward the outside direction of the discharge pipe with respect to the central axis of the discharge pipe, the discharge of seawater discharged through the discharge pipe Provided is an outboard effluent diffusion device, characterized in that inducing diffusion.

Each of the first wing plate and the second wing plate may be installed such that one end portion along the longitudinal direction of the discharge pipe is introduced into the inside of the discharge pipe, and the other end portion is protruded outside the discharge pipe. .

Each of the first wing plate and the second wing plate may have a vertical distance along the longitudinal direction of the discharge pipe from one end to the other end, 0.5 to 1.5 times the diameter of the discharge pipe.

Alternatively, each of the first wing plate and the second wing plate may have a vertical distance along the longitudinal direction of the discharge pipe from one end to the other end, the same as the diameter of the discharge pipe.

Each of the first wing plate and the second wing plate may have the same length as a portion that is introduced into the discharge pipe and a portion that protrudes to the outside of the discharge pipe.

The plurality of first wing plates are installed such that one end is positioned at a point where the diameters of the discharge pipes are equally spaced equally in the vertical direction, and the plurality of second wing plates are in the horizontal direction. The diameter of the discharge pipe may be installed so that one end is located at each point equally spaced.

Each of the first wing plate and the second wing plate is provided to be inclined toward the outer direction of the discharge pipe as it goes from one end to the other end, and may have an inclination angle θ in the outer direction with respect to the central axis of the discharge pipe have.

In the present invention, the first wing plate and the second wing plate, which are designed in consideration of the size of the diameter of the discharge pipe, are connected to each other by welding to produce an integral structure, and then a part of the integral structure is formed inside the discharge pipe. It can be fixed by welding and the part in contact with the discharge pipe by welding.

In addition, another aspect of the present invention for achieving the above object, in the ship equipped with a discharge pipe for discharging the seawater used for the purification of exhaust gas from the sulfur oxide reduction device provided in the vessel outboard, the discharge pipe By providing a diffusion means for diffusing the discharge water at the end of the ship, it characterized in that the pH at a point 4m away from the hull of the vessel satisfies 6.5 or more, provides an outboard discharge water diffusion device.

According to the present invention, the seawater used in the scrubber is rapidly discharged by the diffusion device installed at the outlet of the discharge pipe during the outboard discharge of the seawater, thereby reducing the risk to marine organisms caused by acidic discharged water and prescribed by IMO. There is an effect that can easily satisfy the regulatory standards.

In particular, the present invention by installing a diffusion means for diffusing the discharged water at the end of the discharge pipe, the pH at a point 4 m away from the ship's hull satisfies 6.5 or more, thereby reducing the risk to marine life by acidic discharged water It is effective.

1 is a view schematically showing an exhaust gas treatment system to which an open-loop type scrubber is applied.
Figure 2 is a perspective view showing that the outboard discharge water diffusion device according to the present invention is installed in the discharge pipe.
It is the figure which looked at FIG. 2 of FIG. 3 from A direction.
4 is a side cross-sectional view of FIG. 2 viewed from the direction B.
5 is a view showing the results of the flow analysis of the existing outboard discharge pipe.
6 is a view showing the results of the flow analysis of the discharge pipe is installed off-board effluent diffusion device according to the present invention.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the contents described in the accompanying drawings, which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. The same reference numerals in each drawing denote the same members.

2 is a perspective view showing that the outboard discharge water diffusion apparatus according to the present invention is installed in the discharge pipe, and FIG. 2 of FIG. 3 is viewed from the A direction (from inside the pipe), and FIG. 4 is a side cross-sectional view of FIG. 2 from the B direction to be.

Referring to FIG. 2, the discharge water diffusion device 100 according to the present invention may be installed at an outlet end of a discharge pipe 200 for discharging seawater used in a scrubber (not shown) provided on a ship outboard.

That is, the present invention allows the rapid diffusion and dilution of the discharged water by allowing the discharged water discharged to the outboard along the discharge pipe 200 after being used in the scrubber to be diffused by the discharged water diffusion device 100 immediately before passing out of the ship. It is made to meet the regulatory standards (pH 6.5 or higher) prescribed by IMO.

Hereinafter, with reference to FIGS. 2 to 4, the shape characteristics of the effluent diffusion device 100 according to the present invention will be described in detail.

Discharge water diffusion device 100 according to the present invention, the first blade plate 110 is installed in the horizontal direction to the outlet end of the discharge pipe 200, and the discharge end is installed in the vertical direction to the outlet end of the pipe 200 2 includes the wing plate (120).

The first wing plate 110 and the second wing plate 120 may be provided in plural, respectively, and the first wing plate 110 and the second wing plate 120 are installed in a direction orthogonal to each other, or the front or When viewed from the rear, a grid can be achieved. The first wing plate 110 and the second wing plate 120 may be connected by a method such as welding to be manufactured as an integral structure.

In the present invention, the first wing plate 110 is installed such that one end along the longitudinal direction of the discharge pipe 200 is introduced into the interior of the discharge pipe 200, and the other end is protruded to the outside of the discharge pipe 200. Can be installed. However, it is preferable that the other end protrudes to the outside in order to obtain a rapid diffusion effect, but depending on the ship, it may not protrude to the outside if there is a possibility or danger of causing resistance when operating.

At this time, from the point where the one end of the first wing plate 110 is located to the point where the other end of the first wing plate 110 is located, the vertical distance D to the longitudinal direction of the discharge pipe 200 is , It may be formed of 0.5 to 1.5 times the diameter (L) of the discharge pipe 200, more preferably it may be formed the same as the diameter (L) of the discharge pipe (200).

As the length of the vertical distance D increases, the diffusion effect of the discharged water may be improved, but since the length of the protruding part also increases, there is a concern that resistance may occur during the operation of the ship, so the vertical distance D is discharged. It is preferable not to exceed 1.5 times the diameter (L) of the pipe 200.

In addition, the length of the portion that is introduced into the interior of the discharge pipe 200 from the first wing plate 110 and the portion that protrudes to the outside of the discharge pipe 200 may be the same. The reason for this configuration is to secure the fixing stability by sufficiently welding the length of the portion that is introduced into the interior of the discharge pipe 200 from the first wing plate 110 to be fixed by welding inside the pipe, This is to induce effective diffusion of the effluent by the portion protruding from the first wing plate 110 to the outside.

However, the present invention is not necessarily limited to this, and considering the fixed stability of the first wing plate 110 and the diffusion effect of discharged water comprehensively, the first wing plate 110 is drawn into the discharge pipe 200. The length of the portion and the portion projecting to the outside of the discharge pipe 200 may be calculated and designed.

In addition, the first wing plate 110 in the present invention, one end may be installed to be located at a point equal to the diameter (L) of the discharge pipe 200 equally spaced. If an integer number of (n) first wing plates 110 are installed, one end of the first wing plate 110 is respectively at a point at which the diameter L of the discharge pipe 200 is equal to n+1. Can be located. The plurality of first wing plates 110 are installed so that one end ends of the discharge pipe 200 extend parallel to each other.

2 to 4, the aforementioned vertical distance D is formed to be the same as the diameter L of the discharge pipe 200, and two first wing plates 110 are provided to provide the diameter of the discharge pipe 200 ( L) is shown an embodiment that is installed so that one end is located at each point divided into three equal parts.

In addition, in the present invention, the first wing plate 110 may be formed to be inclined toward an outer direction of the discharge pipe 200 as it goes from one end to the other end. In other words, the first wing plate 110 is provided in a form that opens in the outer direction of the discharge pipe 200 based on the central axis of the discharge pipe 200, to induce the diffusion of discharged water discharged through the discharge pipe 200 Can be.

At this time, the inclination angle θ of the first wing plate 110 with respect to the longitudinal axis of the discharge pipe 200 may be formed to be 5° or more, more preferably 10° or more, to induce diffusion of the discharge water. . Through the flow analysis, the present applicant has verified that when the inclination angle θ is less than 5°, the diffusion effect of the effluent is negligible, and when the inclination angle θ is 10° or more, the diffusion effect of the effluent is good.

In addition, when the inclination angle θ is formed to exceed 40°, the diffusion effect of the discharge water may be good, but the first wing plate 110 interferes with the discharge flow at the outlet of the discharge pipe 200, thereby increasing the pipe pressure. And, in severe cases, a phenomenon may occur that the discharge water flows back to the scrubber side. Therefore, the inclination angle θ is preferably 40° or less, more preferably 30° or less, so that no backflow occurs to the discharge pipe 200.

As described above, when the inclination angle θ exceeds 40°, the advantage is that the diffusion efficiency is high. However, the disadvantage is that the overflow of the discharged water may occur as the flow of the discharged water in the pipe becomes slow due to an increase in the back pressure of the pipe diameter. When overflow of discharge water occurs in the discharge pipe 200, the scrubber is forced to shut down (emergency stop). Therefore, the present invention can prevent the overflow of the discharge water and the emergency stop of the scrubber by setting the inclination angle θ to 10 to 40 degrees. In addition, by making the inclination angle θ have the above angle, it is possible to minimize the influence of the discharge water flow in the pipe and maximize the diffusion effect of the outboard water.

That is, in the present invention, the inclination angle θ of the first wing plate 110 with respect to the longitudinal axis of the discharge pipe 200 is preferably 5° to 40°, more preferably 10° to 30° It can be formed of.

In addition, the first wing plates 110 installed opposite to each other based on the center of the discharge pipe 200 may have the same inclination angle θ in opposite directions.

On the other hand, although not shown in the drawing, when the first wing plate 110 is provided with three or more (n≥3), the plurality of first wing plates 110 are outside from the center of the discharge pipe 200 As it is arranged farther away, the inclination angle θ may be gradually increased. That is, the inclination angle θ of the first wing plate 110 far from the center of the discharge pipe 200 is formed larger than the inclination angle θ of the first wing plate 110 close to the center of the discharge pipe 200. Can be. However, even at this time, it is preferable that the inclination angle θ of the first wing plate 110 installed at the outermost angle is 40° or less.

In addition, when the first wing plate 110 is provided in an odd number of three or more, the inclination angle θ of the first wing plate 110 installed at the center of the discharge pipe 200 may be formed at 0°. have.

The characteristics of the first wing plate 110 described above may be applied to the second wing plate 120 as it is. That is, in the present invention, the first wing plate 110 and the second wing plate 120 are different only in the direction in which they are installed inside the discharge pipe 200, and all other shape features may be provided in the same way.

Briefly, in the present invention, the second wing plate 120 is installed such that one end portion along the longitudinal direction of the discharge pipe 200 is introduced into the interior of the discharge pipe 200, and the other end of the discharge pipe 200 It may be installed to protrude to the outside, at this time, from the point where one end of the second wing plate 120 is located to the point where the other end of the second wing plate 120 is located, the length of the discharge pipe 200 The vertical distance D with respect to the direction may be formed at 0.5 to 1.5 times (more preferably 1.0 times) compared to the diameter L of the discharge pipe 200.

In addition, the length of the portion of the second wing plate 120 that is introduced into the interior of the discharge pipe 200 and the portion that protrudes to the outside of the discharge pipe 200 is formed the same, the diameter (L) of the discharge pipe 200 ) Is installed so that one end of the second wing plate 120 is positioned at equal points at equal intervals, as described in the first wing plate 110.

In addition, the second wing plate 120 may be formed to be inclined toward the outer direction of the discharge pipe 200 as it goes from one end to the other end, and the second wing plate 120 is a longitudinal axis of the discharge pipe 200 The angle of inclination with respect to, as in the first wing plate 110, may be preferably 5° to 40°, more preferably 10° to 30°.

In the present invention, the first wing plate 110 and the second wing plate 120 may be manufactured in the same size, and may be installed to be inclined at the same inclination angle based on the central axis of the discharge pipe 200.

Discharge water diffusion apparatus 100 according to the present invention, as described above, the first wing plate 110 and the second wing plate 120 may be made of an integral structure connected by welding, the discharge pipe 200 ) After the size is designed and manufactured in consideration of the diameter (L), it is possible to simply install it by fixing it to the outlet end of the discharge pipe 200 by welding.

In addition, the present invention can be implemented by separately manufacturing the outlet pipe in which the discharge water diffusion device 100 is installed, and connecting the end of the discharge pipe 200 with welding. However, when the discharge pipe 200 is installed in a hole formed in the outer wall of the hull, it will be preferable to fix it to the pipe itself.

Discharge water diffusion device 100 according to the present invention, by rapidly discharging the discharged water in the process of discharged outboard discharged water discharged through the discharge pipe 200, to reduce the risk to marine life caused by acidic discharged water, It has the effect of easily satisfying the regulatory standards prescribed by IMO.

On the other hand, in order to achieve an effect similar to the present invention, a method of expanding the outlet side pipe itself of the discharge pipe 200 may be considered, which requires a change or replacement of the design of the discharge pipe 200, Compared to the present invention in which only the discharged water diffusion device 100 is simply installed, it is not desirable that the operation difficulty is high and the cost is increased.

In general, the outboard discharge pipe 200 provided on the ship may be provided with various diameters (L), but the present invention is simple regardless of the size of the pipe and is designed in size in proportion to the pipe diameter (L). It is characterized in that it provides a possible outboard effluent diffusion device (100).

Therefore, the present invention does not need to design change or replacement of the outboard discharge pipe 200 which is already installed in the existing ship, the discharge pipe 200 by separately manufacturing the discharge water diffusion device 100 in consideration of the existing pipe diameter (L) By simply installing at the outlet end of the, it is possible to achieve the effect to be achieved by the present invention, that is, the effect of satisfying the regulations in the IMO for outboard effluent.

5 and 6, the effect of the installation of the effluent diffusion device 100 according to the present invention can be confirmed.

5 is a view showing the results of the flow analysis of the existing outboard discharge pipe, and FIG. 6 is a view showing the results of flow analysis of the discharge pipe in which the discharge water diffusion device according to the present invention is installed. 5 and 6 is tested by applying a discharge pipe having a diameter of 250A.

5 and 6, in the existing outboard discharge pipe (FIG. 5) in which the discharge water diffusion device is not installed, the pH at a point 4 m away from the ship is measured as 6.4, which does not satisfy the IMO regulations, but the present invention In the discharge pipe (FIG. 6) equipped with the outboard discharge water diffusion device according to the pH of the point 4 m away from the vessel is measured 7.0, it can be seen that it meets and exceeds the criteria prescribed by the IMO.

The present invention is not limited to the described embodiments, and it is obvious to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

100: Drainage diffusion device
110: first wing plate
120: second wing plate
200: discharge piping

Claims (9)

In the outboard discharge water diffusion device installed at the outlet end of the discharge pipe for discharging the seawater used for the purification of exhaust gas in the ship outboard,
A plurality of first wing plates installed in a horizontal direction at an outlet end of the discharge pipe; And
It includes a plurality of second wing plate is installed in the vertical direction at the outlet end of the discharge pipe,
The discharge pipe has the same diameter from the inner flow path to the outlet end so as not to include an extension at the outlet end,
In the first wing plate and the second wing plate, parts orthogonal to each other are connected by welding to form a grid-shaped structure,
In the first wing plate, at least a portion of both short sides in the horizontal direction is directly connected and fixed to the inner wall of the discharge pipe, and the second wing plate has at least a portion of both short sides in the horizontal direction attached to the inner wall of the discharge pipe. Directly connected and fixed,
Each of the first wing plate and the second wing plate is installed to be inclined toward the outside direction of the discharge pipe with respect to the central axis of the discharge pipe to induce diffusion of seawater discharged through the discharge pipe,
In each of the first wing plate and the second wing plate, one end portion along the longitudinal direction of the discharge pipe is installed to be drawn into the inside of the discharge pipe, and is fixed to the inner wall of the discharge pipe by welding, and the other end of the discharge pipe is discharged. Characterized in that it is installed to protrude to the outside of the discharge pipe for rapid diffusion of the discharged water discharged to the pipe,
Drainage device for outboard discharge.
The method according to claim 1,
Each of the first wing plate and the second wing plate is provided to be inclined toward an outer direction of the discharge pipe as it goes from one end to the other end, and has an inclination angle θ in an outer direction with respect to the central axis of the discharge pipe Characterized by,
Drainage device for outboard discharge.
The method according to claim 2,
Each of the first wing plate and the second wing plate is characterized in that the vertical distance along the longitudinal direction of the discharge pipe from one end to the other end is formed to be 0.5 to 1.5 times the diameter of the discharge pipe. ,
Drainage device for outboard discharge.
The method according to claim 2,
Each of the first wing plate and the second wing plate, characterized in that the vertical distance along the longitudinal direction of the discharge pipe from one end to the other end is formed to be the same as the diameter of the discharge pipe,
Drainage device for outboard discharge.
The method according to claim 3,
Each of the first wing plate and the second wing plate, characterized in that the length of the portion that is introduced into the interior of the discharge pipe and the portion that protrudes to the outside of the discharge pipe are formed the same,
Drainage device for outboard discharge.
The method according to claim 2,
The plurality of first wing plates are installed such that one end is positioned at a point where the diameter of the discharge pipe is equally spaced at equal intervals with respect to the vertical direction.
The plurality of second wing plates are characterized in that the ends of the discharge pipes are installed at equal points at equal intervals with respect to the horizontal direction.
Drainage device for outboard discharge.
The method according to claim 2,
The inclination angle is characterized in that formed at 40 ° or less so as to prevent the phenomenon of discharge water reverse flow from the outlet of the discharge pipe,
Drainage device for outboard discharge.
The method according to any one of claims 1 to 7,
After the first wing plate and the second wing plate, which are designed in consideration of the diameter size of the discharge pipe, are connected to each other by welding to produce an integral structure, a part of the integral structure is drawn into the discharge pipe and By fixing the portion in contact with the discharge pipe by welding, it is possible to improve the diffusion effect of the discharge water simply by installing the integral structure at the outlet end of the discharge pipe without changing the diameter of the discharge pipe. Made with,
Drainage device for outboard discharge.
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