KR101797250B1 - UV Reactor for Treatment Apparatus of Ship's Ballast Water with improved thermal emission property - Google Patents

Abstract

The present invention relates to an ultraviolet reactor for a ballast water treatment apparatus of a ship having improved heat radiation characteristics.
The present invention relates to a seawater inflow port through which seawater flows; A body through which the seawater introduced into the seawater inlet passes; A seawater outlet through which the seawater passing through the body flows out; A hollow protective pipe disposed inside the body so as to cross the inside of the body in a direction parallel to the ground; An ultraviolet lamp that extends in the longitudinal direction of the protective pipe in the protective pipe and ultraviolet sterilizes seawater passing through the body; A bush assembly including a fixing member which is partially inserted into an opening of the protective pipe at both ends and which is coupled to the ultraviolet lamp, and a connection member which is engaged with the fixing member,
The fixing member is movably provided on the connecting member. The fixing member is provided between the fixing member and the connecting member so as to reduce the impact due to the vibration of the ultraviolet lamp, The spring is to be rebounded.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an ultraviolet ray reactor for a ballast water treatment apparatus for ships having improved heat radiation characteristics,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultraviolet reactor for a ballast water treatment apparatus of a ship, and more particularly, to an ultraviolet reactor for a ballast water treatment apparatus that minimizes variations in the center of gravity of a ship by means of ballast water filled in the ballast tank The present invention relates to an ultraviolet reactor which improves the connection structure of an ultraviolet lamp for sterilizing ultraviolet (UV) light.

In general, ballast tanks installed on ships are to minimize the center of gravity of the ship by loading and unloading of cargo to help safe navigation. In other words, if the ship is loaded full of cargo, the vessel's center of gravity is located below the sea level even if the ballast tank is not filled with ballast water. Therefore, even if external force acts, the ship can navigate safely. The ballast tank is filled with ballast water so that a certain part of the ship can be positioned below the sea level as the ship is shipped.

As described above, the ballast water used for safe operation of a ship has a problem in that it is used as a medium for propagating organisms or pathogens in a specific area to other seas.

The ballast water filled in the ballast tanks may include various marine organisms and pathogens. Since the inflow and outflow of the ballast water are performed in different areas, when the ballast water is introduced, As it flows out to other waters, causes side effects that disturb the environment and the ecosystem.

Therefore, introduction of facilities for treating marine organisms or pathogens contained in ballast water at the time of leakage of ballast water is obligatory.

Fig. 1 shows the construction of a general ballast water treatment apparatus.

As shown in FIG. 1, a general ballast water treatment apparatus 1 includes a pretreatment filter 10 and an ultraviolet reactor 20 to sterilize the inflow or outflow of ballast water.

First, referring to the inflow process of the ballast water, the configuration indicated by "A" in FIG. 1 becomes the ocean, and the configuration indicated by "B" becomes the ballast tank.

When the ballast water is introduced, the valve 21 of the inlet pipe 11 and the valve 22 of the connection pipe 12 are opened and the valve 23 of the branch pipe 13 is closed. The seawater introduced from the ocean A flows into the pretreatment filter 10 through the inflow pipe 11 and is removed through the ultraviolet reactor 20 through the connection pipe 12, 14 to the ballast tank B.

Conversely, if the ballast water outflows, the configuration indicated by "B" in FIG. 1 becomes the ocean, and the configuration marked "A" becomes the ballast tank (ocean and ballast tanks are connected by a common line ). When the ballast water flows out, the valve 21 of the inlet pipe 11 and the valve 22 of the connecting pipe 12 are closed, and the valve 23 of the branch pipe 13 is opened. The seawater flowing out of the ballast tank A flows into the ultraviolet reactor 20 through the branch pipe 13 and is subjected to a sterilization treatment process and then discharged to the sea B through the discharge pipe 14.

The ballast water used in ships in accordance with the recent IMO (International Maritime Organization) agreement requires sterilization treatment.

Various methods such as electrolysis, heat treatment, ultraviolet light irradiation, and membrane separation can be applied to the sterilization treatment for the ballast water treatment. However, since the ultraviolet light irradiation treatment does not require addition of a chemical substance and is easy to control, .

The ultraviolet reactor 20 described above is for irradiating ultraviolet rays to seawater and has a plurality of ultraviolet lamps (not shown) for irradiating ultraviolet rays. The seawater passing through the ultraviolet reactor 20 is sterilized by the ultraviolet rays irradiated from the ultraviolet lamp.

Such ultraviolet lamps may be damaged by the vibration of the ship or the heat generated by the ultraviolet lamp. Such damage is particularly generated at the connection portion connecting the ultraviolet lamp to the ultraviolet reactor body.

It is necessary to provide a connection structure of an ultraviolet lamp which is resistant to vibration of the ship or heat generation of the lamp in order to prevent the efficiency of the reactor from being reduced as the ultraviolet lamp is broken.

Korean Patent Laid-Open Publication No. 10-2008-0090098

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art and it is an object of the present invention to provide an ultraviolet reactor for a ballast water treatment apparatus capable of effectively preventing damage to an ultraviolet lamp by improving the connection region between an ultraviolet reactor and an ultraviolet lamp do.

In order to accomplish the above object, according to the present invention, there is provided an ultraviolet reactor for a ballast water treatment apparatus of a ship, comprising: a seawater inlet through which seawater flows; A body through which the seawater introduced into the seawater inlet passes; A seawater outlet through which the seawater passing through the body flows out; A hollow protective pipe disposed inside the body so as to cross the inside of the body in a direction parallel to the ground; An ultraviolet lamp that extends in the longitudinal direction of the protective pipe in the protective pipe and ultraviolet sterilizes seawater passing through the body; A bush assembly including a fixing member which is partially inserted into an opening of the protective pipe at both ends and which is coupled to the ultraviolet lamp, and a connection member which is engaged with the fixing member,
The fixing member is movably provided on the connecting member. The fixing member is provided between the fixing member and the connecting member so as to reduce the impact due to the vibration of the ultraviolet lamp, The spring is to be rebounded.
Wherein the fixing member comprises a first fixing portion formed with a projection for increasing a plurality of heat transfer efficiencies on an outer circumferential surface thereof and a first extending portion extending from the first fixing portion, A second extending portion coupled with the first extending portion, and a second fixing portion extending from the second extending portion.
And a clearance is formed between the rear end face of the first fixing portion of the fixing member and the front end face of the second extending portion of the connecting member.

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As described above, the present invention improves the connection structure between the ultraviolet reactor and the ultraviolet lamp so that the ultraviolet lamp can reduce the impact caused by the vibration of the ship to prevent breakage of the ultraviolet lamp, and even if thermal expansion occurs, It is possible to protect the user.

1 is a block diagram of a general ballast water treatment apparatus.
2 is a perspective view of an ultraviolet reactor according to an embodiment of the present invention.
3 is a cross-sectional perspective view of the ultraviolet reactor shown in Fig. 2 cut in half in the longitudinal direction.
4 and 5 illustrate an ultraviolet reactor equipped with an ultraviolet lamp assembly according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that the technical idea of the present invention and its essential structure and action are not limited by this embodiment.

FIG. 2 is a perspective view of an ultraviolet reactor 100 according to an embodiment of the present invention, and FIG. 3 is a cross-sectional perspective view of the ultraviolet reactor 100 of FIG. 2 cut in half in the longitudinal direction. In FIG. 2, the body 300 is shown transparently for convenience of explanation.

2 and 3, the ultraviolet reactor 100 includes a seawater inflow conduit 400 (hereinafter, referred to as " inflow conduit ") through which seawater introduced from a marine or ballast tank (not shown) can be introduced into the reactor 100 through a seawater inflow port 401 A body 300 through which the seawater introduced through the seawater inflow conduit 400 passes and a seawater outlet conduit through which the seawater passing through the body 300 can be discharged through the seawater outlet 501 500).

The body 300 according to the present embodiment is formed in a substantially rectangular shape and a seawater inflow conduit 400 and a seawater outflow conduit 500 are formed on the bottom and top of the body 300 in the longitudinal direction of the body 300, respectively .

The seawater introduced into the seawater inflow conduit 400 through the seawater inflow conduit 401 passes through the perforated plate 402 to fill the inside of the body 300 and the seawater passing through the body 300 passes through the seawater outflow conduit 500 And then flows out to the seawater outlet 501 to circulate the seawater in the reactor.

A plurality of ultraviolet lamp assemblies 200 are connected to the body 300. The ultraviolet lamp assemblies 200 each include an ultraviolet lamp 210.

A power supply unit (not shown) is connected to the ultraviolet lamp 210. When power is supplied, the ultraviolet lamp 210 emits ultraviolet rays to sterilize seawater passing through the inside of the body 300.

The ultraviolet lamp assemblies 200 are disposed at different heights to increase the bactericidal effect of seawater.

Referring to FIG. 3, the ultraviolet lamp assembly 200 includes a long ultraviolet lamp 210, an ultraviolet lamp 210 disposed to cross the inside of the body 300 in a direction parallel to the ground, And a connection structure 230 for connecting the ultraviolet lamp 210 and / or the protective tube 220 to the body 300. The ultraviolet lamp 210 is connected to the ultraviolet lamp 210 and /

4 and 5 illustrate an ultraviolet lamp assembly 200 according to an embodiment of the present invention.

Both ends of the protection pipe 220 extend through the outer wall of the body 300. An o-ring 281 is disposed between the protective pipe 220 and the body 300 so that the sea water inside the body 300 is not leaked to the outside.

The ultraviolet lamp 210 inside the protective tube 220 is isolated from seawater and protected from seawater since both ends of the protective tube 220 extend to penetrate the outer wall of the body 300.

The protective pipe 220 according to the present embodiment is formed of a transparent quartz material so that ultraviolet rays emitted from the ultraviolet lamp 210 can be transmitted to the seawater.

The both ends of the ultraviolet lamp 210 are fixed by bushing assemblies 231 and 232 into which a part of the ultraviolet lamp 210 is inserted through the openings formed at both ends of the protective tube 220 and the bushing assemblies 231 and 232 And is fixed to the body 300 by lids 233 and 234 coupled to the outer wall of the body 300.

The bushing assemblies 231 and 232 include a fixing member 231 inserted into the protective tube 200 and engaged with the ultraviolet lamp 210 and a connecting member 232 fixed to the body 300 by a cover .

The fixing member 231 includes a first fixing portion 241 having a large diameter for fixing the terminals 211 formed at both ends of the ultraviolet lamp 210 and a second fixing portion 241 extending from the first fixing portion 241, The first extension 242 has a smaller diameter than the first extension 242. The first fixing part 241 is formed so as to surround the terminal 211 of the ultraviolet lamp.

The first fixing part 241 has a plurality of protrusions 243 extending in a direction perpendicular to the center axis of the ultraviolet lamp 210. As the projection 243 extends in the vertical direction, the surface area of the first fixing portion 241 can be maximally increased by the plurality of projections 243.

The diameter of the first fixing part 241 including the height of the protrusion 243 is slightly smaller than the inner diameter of the protection tube 220 so that the first fixing part 241 is fixed by the heat transmitted from the terminal 211 of the ultraviolet lamp 210, So that the protective tube 220 is not damaged.

Generally, when power is supplied to the ultraviolet lamp 210, the largest heat is generated at the terminals 211 located at both ends of the ultraviolet lamp 210. The heat generated at the terminal 211 is transferred to the first fixing portion 241 and discharged to the sea water, thereby cooling the terminal 211.

If the heat generated in the terminal 211 can not be discharged to the sea water, a failure may occur in the ultraviolet lamp 210 or a lamp may be broken in severe cases.

Since the surface area of the first fixing portion 241 is greatly increased by the protrusion 243, the heat transfer efficiency for transferring the heat generated in the terminal 211 to the seawater outside the protective pipe 220 is greatly increased .

A first through hole 271 is formed in a longitudinal direction of the first extending portion 242 at a center of the first extending portion 242 having a smaller diameter than the first fixing portion 241. The first through hole 271 contacts the terminal 211 and communicates with the terminal 211.

The connecting member 232 includes a second fixed portion 251 having a large diameter fixed to the body 300 and a second fixed portion 251 extending from the second fixing portion 251 and having a smaller diameter than the second fixing portion 252. [ 2 extended portion 252. [ A second through hole 272 is formed in the center of the second extending portion 252.

The first extended portion 242 of the fixing member 231 is inserted into the second through hole 272 formed in the second extended portion 252 of the connecting member 232 and is movable in the second through hole 272. [

The connecting member 232 is fixed to the body 300 by lids 233 and 234 coupled to the outer wall of the body 300.

The covers 233 and 234 include a spacer member 233 coupled to the outer wall of the body 300 and a cover member 234 coupled to the rear end surface of the spacer member 233 to protect the bushing assemblies 231 and 232 .

The bushing assemblies 231 and 232 are inserted into the third through holes 273 formed at the center of the spacer member 233. The bushing assemblies 231 and 232 are inserted into the space member 233, 2 fixing portion 252. [0156]

4, protrusions 292 are formed on the inner circumference of the spacer member 233 at intervals corresponding to the thickness of the flange 253 protruding from the rear end of the second fixing portion 252 of the connecting member 232, A snap ring 291 made of a material is formed.

Here, the term "rear end" means the end side far from the center portion of the ultraviolet lamp 220. [ The term "shear " as the contrary means the end side opposite to the term" rear end ".

The spacer member 233 is first coupled to the outer wall of the body 300 and then the bushing assemblies 231 and 232 are inserted into the protective pipe 220 through the third through hole 273 to assemble the connection structure 230. [ The bushing assemblies 231 and 232 can be fixed with respect to the body 300 by placing the flange 253 between the protrusion 292 and the snap ring 291. [ Thereafter, the flange 261 of the cover member 234 is engaged with the rear end surface of the spacer member 233.

The cover member 234 is formed with an extension portion 262 extending to the rear end portion. Various cables or equipment can be accommodated in the inner space of the extension portion 262.

A fourth through hole 274 is formed at the rear end of the extension portion 262. 4, the first through-hole 271, the second through-hole 272, the third through-hole 273, and the fourth through-hole 274 communicate with each other.

Therefore, power can be supplied to the lamp by connecting a wire (not shown) connected from a power supply unit (not shown) to the terminal 211 of the ultraviolet lamp 210 through the through holes 271 to 273.

The diameter of the first fixing part 241 including the height of the protrusion 243 is formed to be smaller than the inner diameter of the protective pipe 220 so that the first fixing part 241 The protective tube 220 can be protected even when the protective tube 220 is thermally expanded in the radial direction.

4, a predetermined clearance (not shown) is formed between the rear end face of the first fixing portion 241 of the fixing member 231 and the front end face of the second extending portion 252 of the connecting member 232 according to the present embodiment S can be formed so that the ultraviolet lamp 210 can be protected even when the fixing member 231 and / or the connecting member 232 are thermally expanded in the longitudinal direction by the heat transmitted from the terminal 211.

Hereinafter, this will be described in detail with reference to Fig.

5, the length t ₁ of the ultraviolet lamp 210 and the total length of the first fixing portion 241 of the fixing members 231 facing each other are set so that the two terminals 211 ) (t ₃₎ the sum of the length (2 × t ₂₎ obtained by subtracting the length of it so as to be smaller than the distance (t ₄₎ between the front end surface of the second extension portion 252 of the two connecting members 232 which faces . At this time, the length (t ₄ ) - the length (t ₃ ) = 2 × the length (S) of the clearance (2S).

It will be understood that the length of the clearance S can be adjusted in consideration of the coefficient of thermal expansion of the fixing member 231, which is a metal.

On the other hand, the ultraviolet lamp 210 may vibrate in the longitudinal direction due to the vibration of the ship. At this time, if the fixing member 231 is completely free of the connection member 232, an impact may be applied to the ultraviolet lamp 210 so that the lamp may be broken.

Referring again to FIG. 4, a coil spring 240 is disposed to enclose the second extension 252 of the coupling member 232. The front end of the coil spring 240 is in contact with the rear end surface of the rear end protrusion 242 of the fixing member 231 and the rear end is in contact with the front end surface of the second fixing portion 251 of the connecting member 232.

The coil spring 240 applies an elastic force to the center of the ultraviolet lamp 210 between the fixing member 231 and the connecting member 232 to prevent the fixing member 231 from suddenly colliding with the connecting member 232 do.

Accordingly, even when the ultraviolet lamp 210 vibrates in the longitudinal direction due to the vibration of the ship, it is possible to prevent the end of the ultraviolet lamp 210 from being damaged and being damaged.

100: ultraviolet reactor
200: ultraviolet lamp assembly
210: ultraviolet lamp
220: Protector
230: connection structure
231: Fixing member
232: connection member
233:
234: cover member
300: Body
400: Seawater inflow channel
500: Sea water outflow channel

Claims (3)

1. An ultraviolet reactor for a ballast water treatment apparatus of a ship,
A seawater inlet through which seawater flows;
A body through which the seawater introduced into the seawater inlet passes;
A seawater outlet through which the seawater passing through the body flows out;
A hollow protective pipe disposed inside the body so as to cross the inside of the body in a direction parallel to the ground;
An ultraviolet lamp that extends in the longitudinal direction of the protective pipe in the protective pipe and ultraviolet sterilizes seawater passing through the body;
A bushing assembly including a fixing member, which is partially inserted into an opening of both ends of the protective pipe, and which is engaged with the ultraviolet lamp, and a connection member which is engaged with the fixing member;
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Wherein both open ends of the protective tube pass through the wall of the body,
Wherein the fixing member is movably provided to the connecting member,
Wherein a coil spring is mounted between the fixing member and the connecting member so as to reduce the impact caused by the vibration of the ultraviolet lamp. The method according to claim 1,
Wherein the fixing member includes a first fixing portion having a projection for increasing a plurality of heat transfer efficiencies on an outer peripheral surface thereof and a first extending portion extending from the first fixing portion,
Wherein the connecting member comprises a second extending portion coupled with the first extending portion of the fixing member and a second fixing portion extending from the second extending portion. 3. The method of claim 2,
And a clearance (S) is formed between a rear end face of the first fixing portion of the fixing member and a front end face of the second extending portion of the connecting member.

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