KR100942868B1 - For purification water aeration device - Google Patents

Abstract

PURPOSE: An aerator for water purification is provided, which can keep seawater of an aquarium clean in a long term and maintain fish fresh. CONSTITUTION: An aerator for water purification comprises an inlet in which seawater is inhaled; a casing(100) in which an outlet in which the seawater is pumped is included; a motor(200) which is installed with the casing and is equipped so that a driving shaft can revolve; and an impeller which is installed on a driving shaft of the motor in the internal space of a casing. The impeller includes a plurality of veins which disperse oxygen into minute particles.

Description

Aeration device for water purification {For purification water aeration device}

The present invention relates to an aerator for supplying oxygen to an aquarium or fish farm to increase dissolved oxygen and improve water quality. More specifically, the present invention relates to an oxygen pump in an impeller of a pump that pumps and circulates seawater in an aquarium. By dispersing the particles into fine particles and installing the aeration unit in the pumping pipe to further disperse the oxygen particles into fine particles so that the dissolved oxygen in the sea water is effectively increased and the water quality is improved. The present invention relates to an aeration device for water purification that maintains a fresh state by increasing the activity of fish and shellfish as well as greatly reducing the management cost of the aquarium.

In general, fish markets and various sushi restaurants use aquariums to store and store fish and shellfish as live fish, and these aquariums generate large amounts of various foreign substances such as excreta and scales of fish and shellfish while the seawater is accumulated therein. Accumulate on the bottom of your aquarium.

These various foreign substances are gradually decomposed by the microorganisms over time, gradually dissipate dissolved oxygen of seawater, and also increase the decomposing substances such as nitrate ions (NO3-) and ammonium ions (NH4 +). In addition, as the nutrients increase, the water quality deteriorates rapidly, and various bacteria are breeding, which is a major cause of death and disease of fish and shellfish.

On the other hand, when the seawater in the aquarium is exchanged, the seawater is first purified and supplied to the aquarium water, or the deep water of the relatively clean sea is used, but as the water quality of the aquarium deteriorates rapidly, the water is frequently required. It is a setting that does not require a small exchange cost.

In particular, in the summer, when the temperature is high, the water quality of the aquarium is further deteriorated. Therefore, high infectious bacteria such as Vibrio choleroe or infectious bacteria such as cholera may occur in fish and shellfish. There was a difficulty in securing.

Therefore, in order to solve the problem of aquarium water, the conventional aquarium pumps the water with a pump to circulate while supplying oxygen to increase the amount of dissolved oxygen in the water, removing bubbles such as bubbles, and filtering with a filter to improve the water quality of the water. An apparatus is provided.

Conventionally, the water purification device of an aquarium uses a Venturi nozzle to increase the amount of dissolved oxygen by supplying oxygen to water pumped by a pump, while purifying water by removing floating matters such as bubbles or scales. Since the oxygen supplied through the turrinozzle is not dispersed as fine particles, the amount of dissolved oxygen was not as high as necessary.

In other words, when oxygen supplied to the water is not dispersed as fine particles, the contact rate between the water and oxygen is lowered and the oxygen dissolution efficiency is lowered. Therefore, the dissolved oxygen cannot be increased as effectively as necessary and the water of the aquarium is frequently reduced as the water purification ability is lowered. I needed to exchange.

Therefore, the oxygen supplied to the water is dispersed and aerated to increase the dissolution efficiency of oxygen to increase the dissolved oxygen efficiency, and to improve the water quality to keep the aquarium water clean without changing the aquarium water for a long time, thus reducing the management cost of the aquarium. I need to do it.

The present invention is a technique devised to improve the problems according to the conventional water purification device of the aquarium, by effectively increasing the dissolved oxygen of the sea water and improving the water quality to maintain the clean state without changing the seawater of the aquarium for a long time to maintain the maintenance cost of the aquarium In order to not only drastically reduce, but also maintain the freshness of fish and shellfish, the oxygen impellers are dispersed in fine particles in the pump's impeller that pumps and circulates the seawater in the aquarium, while the oxygen particles are further reduced in the aeration unit installed in the pumping pipe. It is a main object of the present invention to provide an aeration device for purifying water, which is dispersed and aerated to increase the dissolution efficiency of oxygen.

The present invention is to realize the desired object as described above,

A casing having an intake port through which sea water is sucked and a discharge port through which sea water is pumped; A motor coupled to the casing and provided to rotate the drive shaft; Impeller coupled to the drive shaft of the motor in the inner space of the casing and pumping the suction of seawater at high speed rotation; including, the impeller is implemented in one side of the circular plate in the axial direction to disperse oxygen to fine particles aeration It includes two vanes, the aeration unit is installed in the pumping pipe coupled to the discharge port of the casing, the aeration unit for dispersing the oxygen by dispersing the fine particles;

According to an embodiment of the present invention, by dispersing oxygen as fine particles in an impeller of a pump that pumps and circulates seawater in an aquarium, while further dispersing oxygen particles as fine particles in an aeration unit installed in the pumping pipe, As the oxygen dissolution efficiency is increased, the dissolved oxygen in the seawater is effectively increased and the water quality is improved, keeping the aquarium's seawater clean without long-term exchange, which greatly reduces the management cost of the aquarium and increases the activity of the fish and shellfish. To provide the effect of maintaining.

Hereinafter, the configuration according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 8.

First, the main gist in the embodiment of the present invention is to disperse oxygen in the aquarium's seawater as fine particles to effectively increase the dissolved oxygen in the seawater, and to improve the water quality so that the aquarium's seawater remains clean without long-term exchange. Not only will it significantly reduce management costs, but it will also keep fish and shellfish fresh and fresh.

Next, looking at the main configuration of the aeration device for purifying water according to the embodiment of the present invention, the casing 100 is provided with a suction port 110 and the discharge port 120 is pumped sea water; A motor 200 coupled to the casing 100 and provided to rotate the drive shaft 210; And an impeller 300 coupled to the drive shaft 210 of the motor 200 in the inner space of the casing 100 and pumping suction of seawater at a high speed rotation. The impeller 300 includes a circular plate 310. Implemented in the axial direction on one side of the includes a plurality of vanes 320 for aeration by dispersing oxygen as fine particles, the oxygen is built-in installed in the pumping pipe 540 coupled to the discharge port 120 of the casing 100 It comprises a; aeration unit 400 for aeration by dispersing the fine particles.

In the main configuration of the casing 100 and the motor 200 is preferably applied to the known prior art as shown in Figure 1, where the casing 100 has an internal space in which the impeller 300 is built-in installed In addition, one side is provided with an inlet 110 for suctioning seawater into the center portion, while the other side is provided with an outlet 120 for pumping seawater.

In the above, the motor 200 may be directly fixed to the casing 100 and applied. However, when the motor 200 is used as a submersible pump, the motor 200 may be installed in a separate case, and the casing 100 may be installed in combination. Preferably, when power is supplied to the motor 200, the drive shaft 210 is rotated at a high speed to drive the impeller 300.

In addition, in the above main configuration, the impeller 300 is installed in the inner space of the casing 100, the boss 311 formed on one side of the circular plate 310 is fitted to the drive shaft 210 of the motor 200 is coupled The vane 320 is provided in the axial direction of the motor on the opposite surface of the boss 311 in the circular plate 310.

In the impeller 300, the vanes 320 are implemented in a cylindrical shape in the axial direction on one surface of the circular plate 310, as shown in Figures 2 to 4 in the drawing, spaced apart at regular intervals on a plurality of circumference The vane 320 is preferably manufactured by varying its length and diameter according to the size of the impeller 300, and is made of plastic or stainless steel having excellent corrosion resistance so as not to be corroded by seawater. This is ideal.

The vane 320 may be implemented in a cylindrical shape on one side of the circular plate 310, but in order to further disperse oxygen supplied to the seawater into fine particles, as shown in FIG. 321 may be formed, and in this case, the spiral protrusion 321 breaks and distributes the oxygen droplets supplied to the seawater to a fine size.

Therefore, in the embodiment of the present invention, when the driving shaft 210 is rotated by supplying power to the motor 200, the impeller 300 rotates at a high speed in the inner space of the casing 100 so that the seawater of the aquarium through the suction port 110 is provided. Inhaled and pumped to the discharge port 120, the impeller 300 is centrifugal force acting from the inner center to the outer side by the plurality of vanes 320 when the high speed rotation by the drive of the motor 200 through the inlet 110 At the same time, the seawater is sucked into the central portion and pumped to the discharge port 120 on the outside, and at the same time, the plurality of vanes 320 and the protrusions 321 that rotate the oxygen droplets supplied to the seawater at high speed are dispersed and pumped.

In addition, in the above main configuration, the aeration unit 400 having a function of dispersing oxygen into fine particles is aerated in a zigzag form, interconnected in a semicircular shape at the top and bottom, as shown in FIGS. 410; And a plurality of through holes 420 formed through the bent surface of the aeration blade 410.

In the above, the aeration unit 400 is embedded in the pumping pipe 540 coupled to the discharge port 120 of the casing 100 is installed and built, made of plastic or stainless steel excellent in corrosion resistance to prevent corrosion due to sea water. It is preferable to.

In the aeration unit 400, the aeration blades 410 are bent in a zigzag shape so as to be symmetrically connected to each other in a semicircular shape at the top and the bottom thereof, and according to the length of the pumping pipe 540 and the size of the acid droplets dispersed in the particles. It is manufactured by selectively varying the length, and a plurality of through holes 420 are formed in a surface bent in a zigzag form.

Therefore, when the aeration unit 400 is installed in the pumping pipe 540 in which seawater is pumped through the impeller 300, the seawater pumped as shown in FIG. 7 passes through the aeration blade 410 bent in a zigzag form. While the vortex occurs rapidly, and oxygen droplets supplied to the seawater pass sequentially through the aeration blades 410 and the plurality of through holes 420 that are bent in a zigzag form and are dispersed into finer particles.

When the embodiment of the present invention having such a configuration is applied to the water purification apparatus of the aquarium as shown in FIG. 8, the water purification apparatus 500 of the aquarium is pumped in which the casing 100 and the motor 200 are installed. Chamber 510, an aeration chamber 520 in which oxygen bubbles are aerated in the pumped seawater, a water supply pipe 530 connected to the inlet 110 of the casing 100, and a discharge port 120 of the casing 100. A pumping pipe 540 connected to the pump to pump sea water into the aeration chamber 520, a drain pipe 550 through which the sea water purified from the aeration chamber 520 is discharged, and bubbles generated from the aeration chamber 520. It is implemented as a discharge pipe 560 through which foreign matters such as floats are discharged.

Looking at the operation process of the water purification device 500 and the water purification aeration device according to an embodiment of the present invention, first, the power is supplied to the motor 200, the water supply pipe 530 when the impeller 300 rotates at high speed At the same time, the seawater of the aquarium is sucked into the casing 100 and oxygen is supplied to the water supply pipe 530 through the inlet pipe from the oxygen tank and sucked into the casing 100.

Oxygen droplets sucked into the casing 100 collide with the vanes 320 and the protrusions 321 of the impeller 300 rotating at high speed, and are dispersed as fine particles, and are pumped together with the seawater to the aeration chamber 520 through the pumping pipe 540. In this case, the seawater pumped from the casing 100 passes rapidly through the aeration unit 400 installed in the pumping pipe 540, and vortices are rapidly generated, and the aeration blades 410 in which oxygen droplets dispersed in the particles are bent in a zigzag form. ) And a plurality of through-holes 420 are sequentially hit and dispersed into finer particles while being pumped into the aeration chamber 520 together with seawater.

In the aeration chamber 520, the oxygen droplets dispersed in seawater and fine particles are pumped into the aeration chamber so that oxygen particles are dissolved in the seawater, thereby increasing the amount of dissolved oxygen, while aeration creates airborne bubbles and various foreign substances. Seawater discharged to the outside through the 560, and purified in the aeration chamber 520 is circulated to the aquarium through the drain pipe 550 to improve the water quality of the seawater.

This embodiment of the present invention is dispersed in the aeration unit 400 installed in the pumping pipe 540 dispersed in the aeration unit 400 is pumped by dispersing the oxygen droplets supplied to the sea water in the impeller 300 for pumping and circulating the sea water of the aquarium The oxygen droplets are further dispersed into fine particles and aerated in seawater, thereby increasing the dissolved oxygen efficiency and effectively increasing the amount of dissolved oxygen.

Therefore, the embodiment of the present invention effectively increases the dissolved oxygen amount of the seawater as necessary, thereby improving the water purification and improving the water quality, thereby greatly reducing the maintenance cost of the aquarium by maintaining the clean state without changing the seawater of the aquarium for a long time. In addition, the activity of fish and shellfish can be increased to keep it fresh.

The preferred embodiments of the present invention have been described above with reference to the present invention, and are not limited to the above embodiments, and those skilled in the art through the above embodiments do not depart from the gist of the present invention. Can be implemented in a variety of changes.

1 is a cross-sectional view showing an installation state of the impeller in the embodiment of the present invention.

Figure 2 is a perspective view of the impeller in the embodiment of the present invention.

Figure 3 is a front view showing the impeller in the embodiment of the present invention.

Figure 4 is a side view showing the vane of the impeller in the embodiment of the present invention.

5 is a perspective view showing an aeration unit in an embodiment of the present invention.

Figure 6 is an installation state of the aeration unit in the embodiment of the present invention.

7 is an operational state diagram of the aeration unit in an embodiment of the present invention.

8 is a cross-sectional view showing an installation state of the aeration device according to an embodiment of the present invention.

{Description of symbols for main parts of the drawing}

100: casing 110: inlet

120: discharge port 200: motor

210: drive shaft 300: impeller

310: plate 311: boss

320: vane 321: protrusion

400: aeration unit 410: aeration blade

420: through hole 500: water purification device

510: pumping chamber 520: aeration chamber

530: water supply pipe 540: pumping pipe

550: drain pipe 560: discharge pipe

Claims (5)

A casing 100 having a suction port 110 through which sea water is sucked and a discharge port 120 through which sea water is pumped; A motor 200 coupled to the casing 100 and provided to rotate the drive shaft 210; And an impeller 300 coupled to the drive shaft 210 of the motor 200 in the inner space of the casing 100 and suction pumping the seawater at a high speed rotation. The impeller 300 includes a plurality of vanes 320 implemented in an axial direction on one surface of the circular plate 310 to disperse oxygen into fine particles and aeration. And an aeration unit (400) installed in the pumping pipe (540) coupled to the discharge port (120) of the casing (100) to disperse oxygen into fine particles and to aeration it. The method of claim 1; The vane 320 is The circular plate 310 is implemented in a cylindrical shape in the axial direction, water purification device characterized in that a plurality of spaced apart at regular intervals on a plurality of circumference is installed. The method of claim 2; The vane 320 is aeration device for water purification, characterized in that the projection 321 is formed spirally on the outer peripheral surface of the cylindrical shape. The method of claim 1; Aeration unit 400, An aeration blade 410 connected to the top and bottom in a semicircular shape and bent in a zigzag shape; Aeration device for water purification, characterized in that it comprises a; a plurality of through-holes 420 formed through the bent surface of the aeration blade (410). The method of claim 4; Aeration blade 410 is aeration device for water purification, characterized in that bent in a zigzag form to be symmetrical interconnected in the shape of a semi-circular upper and lower.

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