KR20140119279A - System purifying sea water aquarium - Google Patents

Abstract

The present invention relates to a system for purifying a sea water aquarium and, more specifically, to a system for purifying a sea water aquarium which enables sea water to be continuously used without change of the sea water. The system for purifying a sea water aquarium comprises: an aquarium wherein the sea water is stored; a sump installed in one inner side wall to be detached so as to circulate and purify the sea water in the aquarium; and a skimmer installed inside the sump to be detached. The sump comprises: a sea water storage part wherein the sea water is supplied from the aquarium and stored; a sea water purification part wherein the skimmer is installed and the sea water moved from the sea water storage part is purified; and a purified water storage part wherein the water purified in the sea water purification part is supplied and stored, and discharged into the aquarium, thereby allowing the sea water to circulate the sea water storage part, the sea water purification part and the purified water storage part in the sump, and the aquarium so as to be purified.

Description

System purifying sea water aquarium}

The present invention relates to a seawater aquarium purification system capable of continuously using seawater stored in a seawater aquarium without replacing it.

Recently, the demand for pets due to the development of children's emotions has increased in the home. The number of singles has increased, and the mystery of fish and sea can be tasted to suit the loneliness and human alienation of urban life due to the nuclear family and aging. The number of hobbyists is increasing, and the sea water ornamental fish industry is showing great interest.

Generally, a seawater aquarium is used to preserve the aquarium fish. Inside the aquarium a proper amount of oxygen and temperature seawater should be maintained to allow the aquarium fish to survive for a long time.

However, in the seawater stored in the seawater aquaria, a considerable amount of foreign matter such as floating matters, dissolved organic matter, and excreta of the sea water ornamental fish is accumulated in the bottom of the aquarium and decomposed by the microorganism over time, so that the dissolved oxygen amount of the seawater is exhausted, And ammonium ions are increased to cause toxicity.

Furthermore, the nutrients increase and the water quality of the seawater deteriorates, and thus, many kinds of germs multiply, resulting in the death of the marine ornamental fish.

Therefore, sea water should be replaced periodically to maintain the environment for the survival of the aquarium fish in the aquarium, but frequent replacement of seawater in the inland area is a significant drawback in cost and time.

Accordingly, a skimmer has recently been used as a device for purifying seawater inside an aquarium without replacing the seawater. The skimmer purifies the water quality of seawater by discharging various foreign substances generated inside the aquarium together with bubble.

Patent Documents 10-1049378 and 10-0983021 disclose conventional skimmer patent documents. However, the skimmer disclosed in the above patent documents merely generates bubbles by injecting air into the water, resulting in a low microbubble generation rate, resulting in a low efficiency of removing foreign substances, and also a disadvantage in that a bubble and a large amount of water are mixed There is a disadvantage that the discharge rate of the bubbles is also limited due to the disadvantage that the discharge rate of the bubbles is large as the water is discharged and the discharge rate of the bubbles is large.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a seawater aquarium purification system capable of continuously using seawater in an aquarium without replacing it.

The above object of the present invention can be also achieved by a sump comprising: an aquarium storing seawater; a sump detachably mounted on one side wall of the aquarium for circulating and purifying seawater of the aquarium; and a skimmer A seawater storage unit for storing the seawater introduced into the aquarium and storing the seawater; a seawater purifier for purifying the seawater which is installed in the skimmer and moving in the seawater reservoir; And a purified water storage unit for storing purified water and discharging the purified water to the aquarium, wherein the seawater of the aquarium is purified by circulating the seawater storage unit, the seawater purification unit, the purified water storage unit, and the aquarium, Can be achieved by providing a seawater aquarium purification system.

According to a preferred aspect of the present invention, the sump further includes a first partition for partitioning the seawater reservoir and the seawater purifier, wherein a lower end of the first partition is spaced apart from the bottom of the sump by a predetermined height, As shown in FIG.

According to another preferred aspect of the present invention, the sump further includes a second partition wall partitioning the seawater purifier and the purified water storage portion, the second partition wall having a lower end spaced apart from the bottom of the sump by a predetermined height, The skimmer may be mounted on an upper end of the second partition.

According to another preferred aspect of the present invention, the sump may further include a third partition formed between the first partition and the skimmer so as to have a length smaller than the first partition to induce the flow of the seawater.

According to another preferred feature of the present invention, the skimmer includes a water inlet and an air inlet formed on one side so as to allow water and air to flow in, and a first outlet protruded on the upper side, A pump for generating bubbles in the interior by the water and air introduced through the air inlet and then discharging the bubbles to the first outlet, and a second pipe having a shape of a circular pipe, A first chamber in which a first cover having a first bubble inlet formed therein and a purified water outlet formed through the first bubble inlet and formed so as to discharge purified water therein is attached to a lower end of the first chamber, A second lid formed in the shape of a circular tube having a smaller diameter than the chamber and formed with a plurality of through holes through which water and bubbles can be discharged, A second chamber in which the first bubble inlet is attached to the upper surface of the first cover so as to be positioned in the circumference of the first chamber, a second bubble inlet formed at the center of the second chamber, A third chamber having a shape of a circular tube and having a lower end attached to an upper surface of the third lid, and a third chamber having a shape of a circular tube and mounted on the inner side of the third chamber; A fourth chamber having a shape of a circular tube having a diameter smaller than that of the third chamber and having a lower end attached to a second bubble inlet of the third cover, Cover.

According to another preferred aspect of the present invention, the skimmer is attached to the outer surface of the first chamber, and the desiccant member having a 'U' -shaped upper engaging portion opened downward so that the upper end of the second partition wall can be fitted .

According to another preferred aspect of the present invention, a through hole may not be formed at a portion vertically above the first bubble inlet of the second cover.

According to another preferred aspect of the present invention, the pump includes a body having a motor therein, a water inlet and an air inlet formed on one side of the body so as to form a space between the body and the body, And a needle wheel inserted into the groove formed in the body and rotated by the motor to generate fine bubbles in the space.

According to another preferred aspect of the present invention, the needle wheel includes a disk-shaped body, a shaft fixed through the center of the body, a plurality of projections formed in a columnar shape on one surface of the body, And an anti-shake ring fitted in one end of the anti-shake ring.

According to the seawater aquarium purification system of the present invention, the seawater of the aquarium is purified while passing through the seawater reservoir and the seawater purifier of the sump, and the purified water circulated and purified through the aquarium is returned to the purifier , And can continue to be used without replacing seawater inside the aquarium.

According to the seawater aquarium purification system of the present invention, the upper and lower ends of the first partition wall are spaced apart from the upper and the bottom of the sump by a predetermined distance, respectively, so that the sludge at the bottom of the sump and the upper- So that a clean state can be maintained.

In addition, according to the seawater aquarium purification system of the present invention, the outflow pressure of the second chamber of the skimmer is lowered so that the bubbles can be well discharged without being broken by the water and in a loose state.

In addition, according to the seawater aquarium purification system of the present invention, a second chamber having a small diameter for introducing and discharging bubbles into the first chamber of the skimmer is separately provided to separate the reaction space and the purified water space, So that the discharge to the purified water outlet of the first chamber can be minimized, and the bubble loss rate is reduced.

1 is a plan view of a seawater aquarium purification system according to an embodiment of the present invention;
2 is a sectional view of the sump of the seawater aquarium purification system shown in Fig.
FIG. 3 is a side view of the seawater aquarium purification system shown in FIG. 1; FIG.
FIG. 4 is a perspective view of the sump of the seawater aquarium purification system shown in FIG. 1; FIG.
FIG. 5 is a perspective view of a skimmer of the seawater aquarium purification system shown in FIG. 1; FIG.
6 is an exploded perspective view of the skimmer shown in Fig.
Figure 7 is a cross-sectional view of the skimmer shown in Figure 5;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the embodiments described below are only for explanation of the embodiments of the present invention so that those skilled in the art can easily carry out the invention, It does not mean anything. In describing various embodiments of the present invention, the same reference numerals are used for components having the same technical characteristics.

1 to 7, a description will be given of a seawater aquarium purification system according to an embodiment of the present invention. 1 to 4, a seawater aquarium purification system includes an aquarium 100, a sump 200, and a skimmer 300, and is characterized by circulating and purifying seawater.

The aquarium 100 stores seawater in which the aquarium fish can be inhabited.

Referring to Figs. 1 to 4, the sump 200 will be described. The sump 200 serves to circulate and purify seawater, and is detachably mounted on one inner side wall of the aquarium 100. The sump 200 may have an upper coupling portion 270 of a 'C' shape opened downward on one side of the upper portion, a plurality of holes (not shown) may be formed on the upper coupling portion 270, The sump 200 can be fixed to the aquarium 100 by fastening the bolts B to the aquarium 100.

The interior of the sump 200 is divided into a seawater storage unit 210, a seawater purification unit 220, and a purified water storage unit 230. The seawater storage unit 210 is a space through which the seawater is introduced and stored in the aquarium 100, and has a plurality of seawater inflow holes into which seawater can be introduced. The seawater flowing into and stored in the seawater storage unit 210 is in a state containing foreign matter. The seawater purifier 220 is a space for purifying the seawater transferred from the seawater reservoir 210 to the skimmer 300. The purified water storage unit 230 is a space in which the purified water purified by the skimmer 300 is moved and stored in the seawater purifying unit 220. The stored purified water is discharged to the aquarium 100 again. A circulation pump 232 may be installed in the purified water storage unit 230 for discharging the purified water, and a discharge pipe 234 may be protruded. The seawater of the aquarium 100 is purified while circulating the seawater reservoir 210, the seawater purifier 220, the purified water reservoir 230, and the aquarium of the sump 200.

The sump 200 may include a first partition 240 separating the seawater reservoir 210 and the seawater purifier 220. In this case, the first partition wall 240 is formed such that the lower end thereof is spaced apart from the bottom of the sump by a predetermined height and the upper end thereof is located at a lower height than the upper end of the sump, And may be spaced apart by a predetermined distance. Accordingly, the seawater stored in the seawater storage unit 210 can be removed from the bottom sludge while moving to the seawater purifier 220 through the passage under the lower part of the first partition 240, May overflow the upper portion of the first partition wall 240 to remove the oil film on the upper portion of the seawater storage unit 210. [

The sump 200 may include a second partition 250 separating the seawater purifying unit 220 and the purified water storage unit 230. In this case, the second partition 250 is formed such that the lower end thereof is spaced apart from the bottom of the sump 200 by a predetermined height, and the skimmer 300 is mounted on the upper end of the second partition 250.

The sump 200 may further include a third partition 260 between the first partition 240 and the skimmer 300 and having a length smaller than that of the first partition 240. The third partition 260 is spaced apart from the first partition 240 by a predetermined distance to guide the flow of the seawater.

The skimmer 300 includes a pump 310, a first chamber 320, a second chamber 340, a third chamber 360, a fourth chamber (not shown), as shown in FIGS. 2 and 5-7. 380, a first lid 330, a second lid 350, a third lid 370, and a fourth lid 390, and may further include a desorption member 322. The chamber, the cover and the desorption member may be made of a synthetic resin material, and in particular, the chamber may be made of a transparent material.

The pump 310 has a water inlet 311 and an air inlet 312 through which water and air can be introduced into one side of the pump 310, And a first outlet 313 formed on the upper side. In this case, the air inlet 312 is formed on the upper side of the water inlet 311, and water and air are simultaneously introduced into the pump 310. An air inlet pipe 312a is connected to the air inlet 312 and an air control valve 312b is connected to the air inlet pipe 312a to control the amount of air to be injected. The amount of air to be regulated by the air control valve 312b can be determined by the amount of bubbles to be filled in the interior of the first chamber 320, which will be described later. For example, when the amount of bubbles is small and the air bubbles remain in the lower portion, a large amount of air is supplied, and when the amount of bubbles is large, air can be supplied in a small amount.

The pump 310 may include a body 314, a cover 316, and a needle wheel 318. The body 314 is provided with a motor (not shown), and a groove 315 is formed in which the needle wheel 318 can be engaged. The cover 316 is coupled to one side of the body 314, and a space portion (not shown) is formed between the cover 316 and the body 314. A water inlet 311 and an air inlet 312 are formed at one side of the cover 316 and a first outlet 313 is formed at an upper side of the cover 316. The needle wheel 318 is inserted into the groove 315 formed in the body 314 and rotated by the motor so that the air introduced into the space inside the body 314 through the air inlet 312 of the cover 316 Is crushed and crushed to produce fine bubbles.

The needle wheel 318 includes a body 318a, a shaft 318b, a projection 318c and an anti-shake ring 318d. The body 318a has a disk shape and may be made of a synthetic resin material. A shaft 318b is fixed to the center of the body 318a and a plurality of protrusions 318c protrude from one side of the body 318a. The shaft 318b is fixed through the center of the body 318a. When the shaft 318b is rotated, the body 318a is rotated together. The shaft 318b may be made of a metal material or a synthetic resin material. A magnet 318e may be coupled to the outer surface of the shaft 318b. The magnet 318e is inserted into the groove of the pump and is supported without being detached. An anti-shake ring 318d may be coupled to one end of the shaft 318b, that is, to one end of the body 318a that penetrates the body 318a. The projections 318c are formed on the one surface of the body 318a in a plurality of protrusions. The projection 318c may have a columnar shape.

The first chamber 320 is formed in the shape of a circular tube and has an open top and a bottom open. A first lid 330 is attached to the lower end of the first chamber 320. The first lid 330 includes a first bubble 321 formed through the surface of the first chamber 320 to allow the first discharge port 313 of the pump 310 to be inserted, And has an inlet 332. Accordingly, the water and bubbles discharged to the first outlet 313 of the pump 310 are moved upward through the first bubble inlet 332 of the first cover 330. The first lid 330 has a purified water discharge port 334 penetrating the surface of the first lid 330 so as to be positioned outside the first bubble inlet 332. The purified water in the first chamber 320 is discharged through the first And is discharged downward through the purified water outlet 334 of the lid 330.

The second chamber 340 is mounted inside the first chamber 320 and has a circular tube shape with a diameter smaller than that of the first chamber 320. The lower end of the second chamber 340 is attached to the upper surface of the first lid 330 so that the first bubble inlet 332 of the first lid 330 is positioned within the circumference of the second chamber 340 . The water and bubbles discharged from the pump 310 flow into the second chamber 340 through the first bubble inlet 332 and the second chamber 340 and the first chamber 320 are separated from each other So that the second chamber 340 substantially functions as a reaction chamber. A second lid 350 is attached to an upper end of the second chamber 340. A through hole 352 is formed in the second lid 350 so that water and bubbles in the second chamber 340 can be discharged upward. . The through hole 352 can have a large number of small diameter. In this case, a through hole may not be formed in a portion of the surface of the second cover 350 corresponding to the vertical upper portion of the first bubble inlet 332. If the vertical upper portion of the first bubble inflow port 332 through which water and bubbles flow is blocked, the outflow pressure can be reduced as compared with the case where the bubbles are blown.

When the water and the bubbles in the second chamber 340 are discharged to the through holes 352 of the second cover 350, the water having a specific gravity tends to descend, but the bubbles having a small specific gravity continue to rise, As a result, the water which is cleaned by the bubbles rising by the foreign matter is filled in the space between the outer surface of the second chamber 340 and the inner surface of the first chamber 320, and the purified water outlet 334 of the first lid 330, .

The third chamber 360 is formed in the shape of a circular tube and accommodates only the bubbles that are coupled to the upper side of the second chamber 340 and rise in the second chamber 340, And the contaminated water may be removed after the third chamber 360 is separated from the second chamber 340. To this end, a third lid 370 is attached to the lower end of the third chamber 360, and the third chamber 360 and the third lid 370 are integrally formed.

The third cover (370) is fitted to the upper end of the first chamber (320) and is detachable. A second bubble inlet 372 is formed at the center of the third lid 370. In this case, the bottom surface of the third lid 370 is upwardly buried toward the second bubble inlet 372 in order to allow the bubble to flow into the second bubble inlet 372. The third lid 370 has a lower end formed in a stepped shape, and is coupled by being fitted to the upper end of the first chamber 320 by a stepped portion (not shown).

The fourth chamber 380 is mounted on the inner side of the third chamber 360 and has a circular tube shape having a diameter smaller than that of the third chamber 360. In this case, the lower end of the fourth chamber 380 may be attached to the second bubble inlet 372 of the third lid 370, and the outer diameter of the fourth chamber 380 may be larger than the diameter of the second bubble inlet 372 As shown in FIG. Accordingly, the spaces between the fourth chamber 380 and the spaces between the fourth chamber 380 and the third chamber 360 are divided into sections so that they are isolated from each other. Accordingly, the bubbles flowing through the second bubble inlet 372 continuously flow into the fourth chamber 380 and then are discharged through the upper end of the fourth chamber 380. The discharged bubbles are discharged to the third chamber 360 and the fourth chamber 380. Eventually, the contaminated water is stored in the space between the third chamber 360 and the fourth chamber 380. When the amount of the contaminated water stored in the third chamber 360 increases, the third chamber 360 may be separated from the second chamber 340, the contaminated water may be discarded, and then the second chamber 340 may be coupled to the third chamber 360.

The fourth lid 390 serves to open and close the upper end of the third chamber 360. When the fourth lid 390 covers the third chamber 360, the fourth lid 390 is discharged to the upper end of the fourth chamber 380 The bubble collides with the lower surface of the fourth cover 390 and moves downward to the space between the third chamber 360 and the fourth chamber 380. [

The desorption member 322 is fixed to the outer surface of the first chamber 320 and has an upper engagement portion 323 to which the upper end of the aquarium wall surface can be fitted. The upper joining portion 323 may be bent in a 'C' shape opened downward.

Hereinafter, the process of cleansing the seawater by the skimmer will be described with reference to FIG. First, when seawater flows into the water inlet 311 of the pump 310 and air flows into the air inlet 312, minute bubbles are generated by the needle wheel 318 rotating inside the pump 310. Then, the fine bubbles are introduced into the second chamber 340 through the first outlet 313 and the first bubble inlet 332 together with the water, and rises together with the water inside the second chamber 340 And is discharged through the through hole 352. Thereafter, the water discharged from the second chamber 340 is filled in the first chamber 320, the fine bubble continues to rise, and then the fourth bubble is introduced through the second bubble inlet 372 of the third lid 370, Chamber 380 as shown in FIG. The fine bubbles are then lifted up and discharged from the fourth chamber 380 and then stored in a space between the fourth chamber 380 and the third chamber 360. The fine bubbles stored therein contain a large amount of foreign matter Since the pollution degree is high in a state, it can be discarded periodically. The purified water purified inside the first chamber 320 is discharged to the lower side of the first chamber 320 through the purified water outlet 334 of the first lid 330.

100: Aquarium 200: Sump
210: Seawater reservoir 220: Seawater purifier
230: purified water storage unit 240: first partition
250: second partition 260: third partition
300: Skimmer 310: Pump
311: Water inlet 312: Air inlet
313: first outlet 314: body
316: cover 318: needle wheel
318a: Body 318b: Shaft
318c: projection 318d: anti-shake ring
320: first chamber 322: detachment member
330: first cover 332: first bubble inlet
334: purified water outlet 340: second chamber
350: second cover 352: through-hole
360: Third chamber 370: Third cover
372: second bubble inlet 380: fourth chamber
390: Fourth cover

Claims (9)

An aquarium in which seawater is stored;
A sump detachably mounted on one side wall of the aquarium for circulating and purifying seawater in the aquarium; And
And a skimmer detachably mounted inside the sump, wherein the sump includes a seawater storage unit into which seawater is introduced and stored in the aquarium, a seawater storage unit installed with the skimmer, And a purified water storage part for storing purified water purified by the seawater purifying part and discharging the purified water to the aquarium, wherein seawater of the aquarium is stored in the seawater storage part, the seawater purification part, the purified water storage part, So as to purify the seawater. The method according to claim 1,
The sump may further include a first partition for partitioning the seawater reservoir and the seawater purifier, wherein the first partition is spaced apart from the bottom of the sump by a predetermined height and the top is located at a lower height than the top of the sump Wherein the at least one of the atmospheric air and the atmospheric air is generated by the atmospheric air. The method of claim 2,
The sump may further include a second partition for partitioning the seawater purifier and the purified water storage part, wherein the second partition is formed such that a lower end thereof is spaced apart from the bottom of the sump to a predetermined height, Wherein the water purification system is installed in the water purification system. The method of claim 3,
Wherein the sump further comprises a third partition formed between the first partition and the skimmer to have a length smaller than the first partition to guide the flow of the seawater. 5. The method according to any one of claims 1 to 4,
The skimmer
A water inlet and an air inlet formed at one side to allow water and air to flow in, and a first outlet formed at an upper side so as to be protruded from the water inlet and the air inlet, And then discharged to the first outlet;
A first lid having a first bubble inlet formed in a shape of a circular tube and penetratingly formed so that the first outlet of the pump can be inserted and a purified water outlet formed so as to discharge purified water from the inside thereof, A first chamber to be attached;
A second lid having a shape of a circular tube having a diameter smaller than that of the first chamber to be mounted inside the first chamber and having a plurality of through holes through which water and bubbles can be discharged, A second chamber having a lower end attached to an upper surface of the first lid so that the first bubble inlet is positioned within the circumference;
A third cover which is fitted on and coupled to the upper end of the first chamber and separable, a second bubble inlet formed at a center portion thereof, and a lower surface inserted upward toward the second bubble inlet;
A third chamber formed in the shape of a circular tube and having a lower end attached to an upper surface of the third cover;
A fourth chamber having a shape of a circular tube having a smaller diameter than that of the third chamber to be mounted inside the third chamber and having a lower end attached to a second bubble inlet of the third lid; And
And a fourth lid that covers the upper end of the third chamber so as to be openable and closable. The method of claim 5,
Wherein the skimmer further comprises a detachment member attached to an outer surface of the first chamber and having a top coupling part of 'D' shape opened downward so that the upper end of the second partition wall can be fitted, . The method of claim 5,
Wherein a through hole is not formed in a portion corresponding to a vertically upper portion of the first bubble inlet of the second cover. The method of claim 5,
A cover having a water inlet and an air inlet formed at one side thereof and a first outlet formed at an upper side of the body, a cover having a body coupled to the body and having a space formed between the body and the body, And a needle wheel inserted into the groove formed in the hollow portion and rotated by the motor to generate fine bubbles in the space portion. The method of claim 8,
The needle wheel includes a body having a disk shape, a shaft fixed through the center of the body, a plurality of protrusions protruding in a column shape on one surface of the body, and an anti-shake ring fitted to one end of the shaft Wherein the water purification system comprises:

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