KR20100005450U - Device for agitating a fluid stored in tank - Google Patents

Abstract

The present invention induces continuous circulation of the fluid by using a transfer pump installed in the tank and nozzles additionally installed in the tank without installing an additional drive motor and blades to agitate the fluid stored in the cylindrical tank. The purpose is to be able to improve the stirring efficiency.

The present invention for achieving the above object, the circulation path is formed to circulate the fluid stored in the tank 10, the transfer pump 12 is installed on the circulation path for the forced circulation of the fluid, and It is characterized in that it comprises a nozzle (14) installed in the tank 10 to communicate with the circulation path to inject the fluid discharged from the transfer pump 12 to facilitate the continuous circulation of the fluid.

Tank, fluid, particles, sedimentation, agitation

Description

Device for agitating a fluid stored in tank

The present invention relates to mixing and preventing sedimentation of liquids or solids and mixtures of liquids stored in cylindrical cylinder tanks, and more particularly in marine tanks for storing and transporting liquids or solids and mixtures of liquids, High pressure injection using a nozzle installed inside the tank without using a stirrer to induce continuous circulation of the fluid stored in the tank, thereby preventing the settling of particles contained in the fluid and inducing a smooth mixing tank It relates to a stirring device for the storage fluid.

In general, in tanks and general storage tanks of ships carrying liquids or a mixture of solids and liquids, particles contained in the fluids are deposited on the bottom of the tanks due to prolonged storage. In order to prevent this, conventionally, a stirrer is installed inside the tank, and a so-called propeller-type stirrer for agitating a fluid stored in the tank by rotating a plurality of blades by a motor in a storage tank of a normal cylindrical mixed fluid is widely used. It's happening.

However, the conventional propeller-type stirrer causes the flow of fluid only around the rotating blade, and the flow force by the blade does not reach the fluid located in a space far from the blade, and in particular, the liquid mud and When storing a mixture having a high specific gravity, the conventional propeller type stirrer has a limitation in agitation of particles precipitated at the bottom of the tank.

As a countermeasure against this, a number of blades are provided in the longitudinal direction of the tank, or a baffle plate is installed to increase agitation efficiency, but these methods not only complicate the structure of the agitation system but also There is a problem that causes excessive power consumption of the drive motor for the rotation of the blades, and high cost for installation and maintenance.

The present invention has been devised in view of the above-mentioned matters, and has a nozzle installed in the tank and the transfer pump installed in the tank without the installation of additional drive motors and blades to agitate the fluid stored in the cylindrical tank. The purpose is to induce a continuous circulation of the fluid and thereby to improve the stirring efficiency of the fluid.

The present invention for achieving the above object, in the stirring device for preventing the precipitation of particles contained in the fluid stored in the tank, the circulation path is formed to circulate the fluid stored in the tank, and the circulation path on A transfer pump installed in the tank to facilitate forced circulation of the fluid, and installed to communicate with the circulation path inside the tank to inject fluid discharged from the transfer pump to prevent sedimentation in the tank and to continuously circulate the fluid. It characterized by comprising a nozzle to.

The circulation path may include a discharge pipe path provided from the discharge port of the tank to the suction port of the pump, and a discharge pipe path provided from the discharge port of the pump to the nozzle. The circulation path may further include a supply pipe branched from the discharge pipe path and installed as a supply port located above the tank.

Opening and closing valves for controlling the opening and closing of the pipeline are installed in the discharge pipe and the supply pipe, respectively, the tank is characterized in that the inner bottom surface is formed to be inclined and the discharge port is formed in the lowest surface of the inclined portion.

The nozzle comprises a horizontal nozzle for guiding the flow direction of the fluid injected in the tank in the arc direction of the tank, and a vertical nozzle for guiding the flow direction of the fluid injected in the tank in the height direction of the tank. It is characterized by including.

The horizontal nozzle is disposed in a plurality of radially in the center of the tank, characterized in that it is set in the arc direction with respect to the center of the tank.

The installation angle of the horizontal nozzle is installed to be inclined downward toward the inner bottom surface of the tank, the vertical nozzle is characterized in that disposed in the upward direction from the center of the tank.

According to the stirring device of the storage fluid in the tank according to the present invention, it is possible to give a high fluidity to the fluid stored in the tank by injecting a high-pressure fluid through a nozzle installed inside the cylindrical tank, the sediment of the fluid circulating It can reduce the occurrence.

In addition, the present invention can achieve more than the same level of efficiency with a lower power consumption than the conventional medium through the improved fluidity of the fluid in the agitation for the fluid stored in the tank, through which the installation and maintenance of the stirring equipment It will provide an economic effect to reduce costs.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1 and 2, the cylindrical tank 10 stores therein a liquid or a mixture of solids and liquids. The mixed fluid stored in the tank 10 may be circulated into / outside the tank 10 through a circulation path, and the transfer path 12 is installed in the circulation path to force the stored fluid. The circulation of phosphorus is promoted.

The tank 10 has a nozzle 14 installed in the center of the tank 10 to communicate with the circulation path therein, the nozzle 14 is a high pressure via the operation of the transfer pump 12 By injecting the fluid sent to the to induce a continuous circulation of the fluid in the tank (10).

To this end, the circulation path from the discharge port 10a of the tank 10 toward the suction port 12a of the transfer pump 12 and the discharge port of the transfer pump 12 A discharge conduit 18 provided toward the nozzle 14 from 12b).

The circulation path further includes a supply pipe 20 branched from the discharge pipe path 18 and installed toward the supply port 10b located above the tank 10, wherein the discharge pipe path 18 and the The supply pipe 20 is provided with opening and closing valves (18a, 20a) for changing the circulation path of the stored fluid by adjusting the opening and closing of each of the pipe.

In addition, the tank 10 has an inner bottom surface formed to be inclined downward toward one direction, and the discharge port 10a is formed at the lowest surface portion located at the bottom of the inclined bottom surface. Accordingly, the fluid stored in the tank 10 flows into the discharge conduit 16 through the outlet 10a, and the fluid introduced into the discharge conduit 16 is sucked in accordance with the operation of the transfer pump 12. It is introduced into the port 12a, pressurized, and then discharged through the discharge port 12b. At this time, the fluid discharged through the transfer pump 12 by the selective opening and closing of the open and close valves (18a, 20a) is supplied to the nozzle 14 through the discharge pipe 18, or the supply pipe 20 Through the supply port (10b) of the tank 10 is directly introduced into the tank 10.

On the other hand, the nozzle 14 is a flow direction for the high-pressure fluid provided through the discharge pipe 18 from the transfer pump 12 in the tank 10 in the circular arc direction of the tank 10 It consists of a horizontal nozzle (14a) for guiding and a vertical nozzle (14b) for guiding the flow direction of the fluid in the height direction of the tank (10) inside the tank (10).

In this case, the horizontal nozzles 14a are disposed radially in a plurality from the center of the tank 10 toward the edge portion, and each installation angle is set in the arc direction with respect to the center of the tank 10. That is, the horizontal nozzle 14a communicates with the discharge conduit 18 while centering the center of the tank 10 at the distal end of the plurality of first connecting conduits 18b radially disposed inside the tank 10. It is installed to face the arc direction as a reference.

At this time, the installation angle of the horizontal nozzle (14a) is installed to be inclined downward at a predetermined inclination angle (α) toward the inner bottom surface of the tank 10, the high-pressure fluid injected through the horizontal nozzle (14a) is The circulation of the sediment in the tank 10 and the flow direction for the stored fluid are induced in the arc direction of the tank 10.

In addition, the vertical nozzle 14b is disposed upward in the center of the tank 10. That is, the vertical nozzle 14b communicates with the discharge conduit 18 while the upper portion of the tank 10 at the tip of the second connecting conduit 18c disposed upward in the vertical direction in the interior of the tank 10. It is installed to face the space.

Accordingly, the high pressure fluid injected through the vertical nozzle 14b induces an upward flow with respect to the fluid stored in the tank 10.

Hereinafter, an operation process and effects on the agitator of the storage fluid in the tank according to the present invention will be described.

First, the fluid stored in another storage space is introduced through the supply port 10b of the tank 10 and stored therein. Particles contained in the fluid stored in the tank 10 is precipitated at the bottom of the tank 10 due to long-term storage to form a precipitate.

At this time, when opening and closing the valve 18a provided in the discharge line 18, the operation of the transfer pump 12 in a state in which the closing valve 20a provided in the supply line 20, the tank 10, the fluid stored therein flows into the discharge conduit 18 through an outlet 10a, and the fluid introduced into the discharge conduit 18 is pumped through the suction port 12a of the transfer pump 12. Flows into.

Subsequently, the fluid introduced into the transfer pump 12 is converted into a high pressure by the pressurizing action of the pump and then supplied to the discharge pipe line 18 through the discharge port 12b, and to the discharge pipe path 18. The provided fluid is injected at high pressure inside the tank 10 through the nozzle 14.

At this time, the fluid injected at high pressure through the horizontal nozzle (14a) and the vertical nozzle (14b) forms a constant flow path circulating along the wall surface of the tank 10 in the interior of the tank (10) By the flow of the fluid, the fluid stored in the tank 10 can be stirred.

In this case, since the horizontal nozzle 14a is inclined downward toward the inner bottom surface of the tank 10, the horizontal nozzle 14a can provide effective fluidity to the precipitate deposited on the bottom surface of the tank 10. In addition, the fluid injected toward the upper portion of the tank 10 through the vertical nozzle 14b not only improves the fluidity of the central portion of the tank 10 having relatively low fluidity within the tank 10. In addition, the fluid injected into the tank 10 together with the horizontal nozzle 14a contributes to imparting fluidity in a constant circulation direction.

As described above with reference to the accompanying drawings for a preferred embodiment of the present invention, the present invention is not limited to the specific embodiments described above, those of ordinary skill in the art By the way, various modifications and variations are possible within the scope of the spirit of the present invention and the equivalent scope of the claims described below.

1 is a view showing a stirring device of the storage fluid in the tank according to the present invention.

FIG. 2 is an enlarged view of the nozzle shown in FIG. 1; FIG.

<Description of Symbols for Main Parts of Drawings>

10-tank 10a-outlet

10b-supply port 12-feed pump

12a-suction port 12b-discharge port

14-Nozzle 14a-Horizontal Nozzle

14b-vertical nozzle 16-discharge line

18-discharge pipeline 20-supply pipeline

Claims (9)

In the stirring device for preventing the precipitation of particles contained in the fluid stored in the tank, A circulation path formed to circulate the fluid stored in the tank; A transfer pump installed on the circulation path to promote forced circulation of the fluid; And Stirring the storage fluid in the tank characterized in that it is provided to communicate with the circulation path inside the tank to inject the fluid discharged from the transfer pump to prevent sedimentation in the tank and to continuously circulate the fluid. Device. The method according to claim 1, The circulation path is a stirring device for storage fluid in the tank, characterized in that consisting of a discharge pipe line provided from the discharge port of the tank to the suction port of the pump, and a discharge pipe line provided from the discharge port of the pump to the nozzle. The method according to claim 2, And said circulation path further comprises a supply line branched from said discharge line and installed as a supply port located above said tank. The method according to claim 3, Stirring apparatus of the storage fluid in the tank, characterized in that the discharge valve and the supply pipe is provided with an on-off valve for controlling the opening and closing of the pipe, respectively. The method according to claim 2, The tank has an inner bottom surface formed to be inclined, and the outlet of the storage fluid in the tank, characterized in that the outlet is formed in the bottom surface of the inclined portion. The method according to any one of claims 1 to 5, The nozzle comprises a horizontal nozzle for guiding the flow direction of the fluid injected in the tank in the arc direction of the tank, and a vertical nozzle for guiding the flow direction of the fluid injected in the tank in the height direction of the tank. Stirring device for storage fluid in the tank, characterized in that provided. The method according to claim 6, The horizontal nozzle is disposed in a plurality of radially in the center of the tank, each installation angle is agitating device of the storage fluid in the tank, characterized in that the arc set in the arc direction with respect to the center of the tank. The method of claim 7, The installation angle of the horizontal nozzle is inclined downwardly installed toward the inner bottom surface of the tank, the stirring device of the storage fluid in the tank. The method according to claim 6, The vertical nozzle is the stirring device of the storage fluid in the tank, characterized in that disposed in the upward direction at the center of the tank.

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