KR20230041151A - Ammonia gas reduction device for land fish farm - Google Patents

Abstract

The present invention relates to an ammonia gas generation reduction device for a land-based fish farm which comprises: a drive motor mounted on a support unit that can remain spaced upward from a water surface of the land-based fish farm with a storage space; a tubular rotating shaft mounted to be supported on the support unit and extending downward from an upper part of the water surface toward a bottom surface of the land-based fish farm to be rotated by power generated by the drive motor, having an air inlet hole formed in a part exposed to the upper part of the water surface through which air can be introduced into the interior, and having an air movement path formed such that the air introduced through the air inlet hole can move downward; and an impeller connected to a lower end of the tubular rotating shaft in communication with the air movement path and introducing the air through the air inlet hole and air movement path when the tubular rotating shaft rotates, discharging the same to a lower part of the storage space, and generating a swirling flow to suppress ammonia generation due to the deposition of foreign substances settled on a bottom surface of the land-based fish farm. According to the ammonia gas generation reduction device for the land-based fish farm, a water flow is generated by suppressing the deposition of foreign substances within the storage space to reduce the generation of ammonia gas, and the amount of dissolved oxygen in the stored water is increased by supporting the introduce of the external air into the storage space to improve the self-purification ability of the water.

Description

Ammonia gas reduction device for land fish farm}

The present invention relates to an ammonia gas generation reduction device for an onshore fish farm, and more particularly, to an ammonia gas generation reduction device for an onshore fish farm built to reduce ammonia gas generation by disturbing foreign substances precipitated inside the land aquaculture farm.

In general, in land-based farms for farming fish and seafood, ammonia gas is generated by the production of protein metabolites such as feed residues, carcasses, and excrement during the aquaculture process. When the concentration of ammonia gas in the water increases, damage such as mass mortality of fish and seafood may occur. In order to prevent such damage, as a method for lowering the ammonia gas concentration in water, breeding water exchange, zeolite spraying, soil improver spraying, and beneficial bacteria spraying are known.

Domestic Patent Registration No. 10-0460022 discloses an ammonia nitrogen removal and sterilization device for a circulation filtration farm, which applies a circulation treatment method that removes filtration and ammonia nitrogen and oxides by leaking water stored in breeding tanks to the outside. .

However, the method of flowing and circulating the water stored in the breeding tank to the outside requires a separate circulation treatment space, and has a disadvantage in that the construction facility is also complicated.

The present invention was devised to improve the above problems, and ammonia gas for land farms increases the amount of dissolved oxygen in the stored water by generating a water flow to suppress the deposition of foreign substances in the breeding water storage space and supporting air inflow. Its purpose is to provide an occurrence reduction device.

Ammonia gas generation reduction device for land farms of the present invention for achieving the above object includes a drive motor mounted on a support unit capable of maintaining a state spaced upward from the surface of the land farm having a water storage space; It is mounted to be supported by the support unit and extends downward from the top of the water surface toward the bottom surface of the land farm, and is installed to be rotated by the power generated by the driving motor, and air is blown into the part exposed to the top of the water surface. a tubular rotary shaft having an air inlet hole through which air can be introduced and an air movement path formed so that the air introduced through the air inlet hole can move downward; It is coupled to the lower end of the tubular rotation shaft in communication with the air movement path, and when the tubular rotation shaft rotates, air is introduced through the air inlet hole and the air movement path and discharged to the lower portion of the water storage space, and the bottom surface of the land farm. and an impeller generating a swirling flow to suppress generation of ammonia due to the deposition of foreign substances precipitated therein.

According to one aspect of the present invention, the foreign matter discharge unit is interlocked with the rotation of the tubular rotary shaft to transfer and filter out foreign substances in the lower part of the water storage space along the extension direction of the tubular rotary shaft; the foreign material discharge unit is further provided with the tubular A feed screw extending spirally along the longitudinal direction on the outer circumferential surface of the rotating shaft, a casing extending along the longitudinal direction of the tubular rotating shaft to surround the screw and fixed to the support unit, and an outer diameter from the casing on top of the casing A discharge pipe extending in an expanding direction and interlocking with the rotation of the tubular rotary shaft to provide a discharge path for the fluid that has risen between the screw and the casing, and the discharge pipe to filter out foreign substances contained in the discharged water discharged through the discharge pipe. or a strainer attached to the casing.

In addition, the impeller includes an upper plate fixed to the lower end of the tubular rotation shaft and formed with a communication hole communicating with the air movement path, a lower plate spaced apart from the upper plate and formed in a size corresponding to the upper plate, and the upper plate and the lower plate. A structure including a plurality of wings extending radially between the upper and lower plates and protruding more outward than the upper and lower plates and spaced apart from each other along the circumferential direction of the upper plate may be applied.

In addition, according to another aspect of the present invention, it is installed to be relatively rotatable on the tubular rotating shaft and rotates on the water surface of the water stored in the water storage space to stir the water stored in the water storage space and at the same time stored in the water storage space An air mixing unit which mixes water and air above the water surface to increase the amount of dissolved oxygen in the water stored in the water storage space; A rotation hub coupled to be rotated relative to the tubular rotation shaft as a rotation center, a plurality of blades protruding in a circumferential direction from the rotation hub and contacting the surface during rotation to generate surface waves, and the rotation hub body It includes a sub-motor that rotates through a power transmission element.

According to the ammonia gas generation reduction device for land farms according to the present invention, a water flow is generated to reduce the ammonia gas generation by suppressing the deposition of foreign substances in the storage space, and by supporting the inflow of external air into the storage space, the water is stored. By increasing the amount of dissolved oxygen in water, it provides the advantage of improving the self-purification ability of water.

1 is a perspective view showing an ammonia gas generation reduction device for a land farm according to a first embodiment of the present invention;
Figure 2 is a front view showing a part of the ammonia gas generation reduction device of Figure 1 cut away,
3 is a side view showing a part of an ammonia gas generation reduction device for a land farm according to a second embodiment of the present invention by cutting it;
4 is a perspective view showing an excerpt of the impeller coupling part of the ammonia gas generation reduction device for land farms according to a third embodiment of the present invention;
5 is a front view showing a part of an ammonia gas generation reduction device for a land farm according to a fourth embodiment of the present invention.

Hereinafter, an ammonia gas generation reduction device for a land farm according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a perspective view showing an ammonia gas generation reduction device for a land farm according to a first embodiment of the present invention, and FIG. 2 is a front view showing a part of the ammonia gas generation reduction device of FIG.

1 and 2, the ammonia gas generation reduction device 100 for a land farm according to the present invention includes a support unit 120, a drive motor 150, a tubular rotary shaft 160, and an impeller 170. .

The support unit 120 is formed to have a support area capable of maintaining a state spaced upward from the water surface 20 of the onshore fish farm 10 having the water storage space 30, and drives a drive motor 150 described below on the upper part of the water surface. It is designed to be equipped with movable elements, including

The support unit 120 includes a pair of floating bodies 121, a pair of bases 122, a pair of vertical frames 123, a connection frame 124, a pair of guide frames 125, a motor support ( 130), and the Shanghai Dong support unit 140.

The floating body 121 is disposed in the water storage space 30 and has sufficient buoyancy to float from the water surface 20. Two floating bodies 121 are applied so as to be spaced apart from each other. As an example, the floating body 121 has a cylindrical shape made of Styrofoam material, and, on the other hand, materials such as foamed urethane and synthetic resin may be applied, or various types of buoys having buoyancy other than the shown shape may be applied. Of course.

The base 122 is formed in a plate shape and is fixed to the upper portion of each floating body 121 . The base 122 may be fixed to the floating body 121 using various fixing members such as ropes and binding brackets formed to support mutual coupling between the floating body 121 and the base 122 . The base 122 is preferably formed of a synthetic resin having good durability and corrosion resistance, but may also be formed of wood or a metal material such as stainless steel.

The connecting member 126 is disposed in a direction crossing the bases 122 spaced apart from each other to interconnect the pair of bases 122 .

The vertical frame 123 is installed to extend upward from the upper surface of the base 122 .

The connection frame 124 interconnects a pair of vertical frames 123 horizontally. The connection frame 124 may be fixed to a pair of vertical frames 123 by welding. Unlike this, the connecting frame 124 may be coupled to the vertical frame 123 with bolts or pins. In this case, a plurality of coupling holes (not shown) spaced apart from each other along the vertical direction are formed in each of the vertical frames 124, , The connection frame 124 is coupled to any one corresponding to a desired height of a plurality of coupling holes respectively formed on the vertical frame 123 to adjust the height from the water surface.

The guide frame 125 is welded to the connection frame 124 and extends vertically. The guide frames 125 extend in the vertical direction and are spaced apart from each other. The guide frame 125 is applied with a C-shaped tube having one of the side surfaces open to form a restraining groove, and the open sides are arranged to face each other, so that the inlet piece 134 of the motor support unit 130 to be described later is drawn in and moves up and down. It provides a moving route.

The motor support unit 130 includes a fixed plate 131 to which the drive motor 150 is fixedly installed, a vertical plate 132 extending upward from an end of the fixed plate 131 toward the guide frame 125, and a vertical plate In 132, a pair of protruding plate members 133 protruded to be positioned between the pair of guide frames 125 and spaced apart from each other, and a restraining groove formed in the guide frame 125 in the pair of protruding plate members 133, respectively. Each includes a pair of pull-in pieces 134 that protrude to be pulled in and move in the vertical direction along the movement path formed by the guide frame 125.

The upper and lower part 140 moves the motor support part 130 up and down so that the separation distance between the impeller 170 and the bottom surface of the land sheep workplace 10 can be adjusted. The upper and lower parts 140 are rotatably fixed to the connecting frame 124 and are fixedly installed to the screw bar 143 extending in the vertical direction and having threads formed on the outer circumferential surface and the vertical plate 132, and the screw bar 143 and It consists of a nut 141 that is screwed together and moves in the vertical direction as the screw bar 143 rotates, and moves the motor support 130 in the vertical direction with respect to the connecting frame 124. Unlike the illustrated example, Shanghai Dongbu raises and lowers the motor support 130 by applying racks, pinions, chains, wires, etc., or, as described above, the motor support 130 is attached to the guide frame by bolts or pins. It can be built to adjust the combined height.

The drive motor 150 is mounted on the motor support part 130 of the support unit 120 and installed to be positioned above the water surface 20 stored in the water storage space 30 of the land farm 10. A geared motor is applied to the drive motor 150, and a BLDC motor, a reversible motor, and the like may be applied in addition.

The tubular rotary shaft 160 is directly coupled to the vertical phase so that it can be rotated by receiving the rotational force of the drive motor 150 directly. The top of the tubular rotation shaft 160 is exposed above the water level stored in the water storage space 30 of the land farm 10. The upper end of the tubular rotation shaft 160 is connected to the drive motor 160 . An air inlet hole 162 through which air can be introduced is formed on the exposed upper portion of the tubular rotary shaft 160 . The inside of the tubular rotation shaft 160 is formed in a tubular shape having a hollow air movement path 164 so that air introduced through the air inlet hole 162 can move to the lower part of the water storage space 30. there is. A boss 165 for bolt coupling with an upper plate 171 of an impeller 170 to be described later is installed on the lower outer circumferential surface of the tubular rotary shaft 160 .

The impeller 170 is bolted to the boss 165 at the lower end of the tubular rotation shaft 160 and includes a disk-shaped upper plate 171 formed with a communication hole 171a communicating with the air movement path 165, and the upper plate 171 A lower plate 172 spaced downward and formed in a size corresponding to the upper plate 171, and between the upper plate 171 and the lower plate 172, both ends are installed in contact with the upper plate 171 and the lower plate 172 And it extends in the radial direction of the tubular rotational shaft 160, but each has a plurality of wings 173 formed to be bent in the same direction.

On the other hand, as shown in FIG. 4 , the wings 173 may be formed so that ends in a direction away from the tubular rotational shaft 160 extend more protrudingly from the upper plate 171 and the lower plate 172 . In this way, when the wings 173 protrude further in the radial direction with respect to the upper plate 171 and the lower plate 172, the agitating force of the water stored in the water storage space 30 can be further increased.

According to this structure, when the tubular rotary shaft 160 and the impeller 170 are rotated by the operation of the drive motor 150 to which power is supplied, a swirling flow is generated in the circumferential direction of the impeller 170, and the impeller 170 Inside, a suction force is generated, and air is introduced into the air passage 165 and the impeller 170 from the air inlet hole 162 and is dispersed along with the water flow in the water storage space. Therefore, the foreign matter deposited on the bottom surface of the water storage space 30 is dispersed and stirred by the water flow generated through the impeller 170, and the self-cleaning ability is also improved by the supplied air.

At this time, the rotation speed of the tubular rotation shaft 160 and the impeller 170 rotated by the drive motor 150 is appropriately applied at a low speed.

In this way, by circulating the water stored in the water storage space 30 and supplying air at the same time, the accumulation of foreign substances such as feed scraps and excrement is suppressed, thereby reducing the generation of ammonia, nitrous acid, and nitrate, and ammonia and nitrous acid generated as a result. , nitrate, etc. are decomposed by microorganisms and converted into amino acids or low-molecular-weight proteins to purify water quality.

On the other hand, it can be built to be linked to the rotation of the impeller 170 to filter out foreign substances in the lower portion of the water storage space by transporting them along the extension direction of the tubular rotational shaft 160, an example of which will be described with reference to FIG. 3. Elements that perform the same functions as in the drawings shown above are denoted by the same reference numerals.

Referring to FIG. 3, the ammonia gas generation reduction device 100 for a land farm according to the present invention is interlocked with the rotation of the tubular rotating shaft 160 to remove foreign substances at the bottom of the water storage space 30 in the extending direction of the tubular rotating shaft 160. There is provided a foreign matter discharge unit 180 for filtering out by conveying.

The foreign matter discharge unit 180 includes a screw 181, a casing 182, a discharge pipe 183, and a strainer 184.

The screw 181 is formed to spirally extend along the longitudinal direction on the outer circumferential surface of the tubular rotary shaft 160 . The screw 181 extends from the bottom of the tubular rotary shaft 160 to the bottom of the air inlet hole 162 .

The casing 182 has an upper end fixed to the fixed plate member 131 and extends downward to be spaced apart from the boss 165 along the longitudinal direction of the tubular rotary shaft 160 while surrounding the screw 181 . A portion of the upper portion of the casing 182 is open so that air can flow in and out of the inside where the screw 181 is formed.

The discharge pipe 183 extends from the casing 182 in the direction in which the outer diameter expands at the top of the casing 182, and is interlocked with the rotation of the tubular rotary shaft 160 to raise the fluid between the screw 181 and the casing 182. provides an outlet path for The discharge pipe 183 is formed at a higher position than the water surface 20.

The strainer 184 may be mounted on the discharge pipe 183 or the casing 182 to filter foreign substances contained in the discharged water discharged through the discharge pipe 183.

When the tubular rotary shaft 160 is rotated in the direction in which the screw 181 lifts and moves the fluid, the fluid between the screw 181 and the casing 172 is moved upward to form the discharge pipe 183. Through this, it is discharged back to the storage space, and in this process, foreign substances other than water are filtered through the sieve 184. As this process is repeated, foreign substances floating in the water storage space 30 can be removed.

Meanwhile, a structure for improving air injection efficiency into the water storage space will be described with reference to FIG. 5 . Elements that perform the same functions as in the previously shown drawings are denoted by the same reference numerals.

Referring to FIG. 5, the ammonia gas generation reduction device 100 for a land farm according to the present invention is relatively rotatably installed on a tubular rotating shaft 160 and rotates on the water surface 20 stored in the water storage space 30. Air mixing that increases the amount of dissolved oxygen in the water stored in the water storage space 30 by stirring the water stored in the water storage space 30 and simultaneously mixing the water stored in the water storage space 30 with the air on the water surface 20 A unit 190 is provided.

The air mixing unit 190 includes a rotary hub 191, blades 192, and a submotor 193.

The rotating hub 191 is installed in contact with the surface of the water at the outer circumferential surface of the tubular rotating shaft 160 . The rotary hub 191 is coupled to be relatively rotatable with respect to the tubular rotary shaft 160 around the tubular rotary shaft 160 by a bearing 194 fixed to the tubular rotary shaft 160 . A driven gear 191a is formed at an upper end of the rotation hub 191 .

A plurality of blades 192 protrude radially from the outer circumferential surface contacting the surface 20 of the rotary hub 191 and are spaced apart from each other along the circumferential direction. When the blade 192 rotates, it comes into contact with the water surface 20 to generate surface waves. The blade 192 is formed to have an airfoil-shaped cross section from its circumferential end to the rotating hub 191. Unlike the illustrated example, the blade 192 may have a rectangular plate shape, and a shape protruding perpendicular to the water surface or obliquely protruding from the water surface may be applied.

The servomotor 193 rotates the rotating hub 1961. In the illustrated example, the driving gear 193a coupled to the rotating shaft of the sub-motor 193 is engaged with the driven gear 191a formed on the rotating hub 191 to transmit power. Unlike the illustrated example, the submotor may be connected with a belt, pulley, or chain to transmit power to the rotating hub 191.

According to this structure, by increasing the amount of dissolved oxygen by increasing the inflow efficiency of the air from the water surface into the water storage space 30 by the rotation of the blade 192, it is possible to further improve the water quality by improving the self-cleaning ability of the water.

According to the ammonia gas generation reduction device for land farms described above, a water flow is generated to reduce the ammonia gas generation by suppressing the deposition of foreign substances in the storage space, and also by supporting the inflow of outside air into the storage space, By increasing the amount of dissolved oxygen in water, it provides the advantage of improving the self-purification ability of water.

120: support unit 150: drive motor
160: tubular rotary shaft 170: impeller

Claims (5)

a drive motor mounted on a support unit capable of maintaining a state spaced upward from the surface of the land farm having a water storage space;
It is mounted to be supported by the support unit and extends downward from the top of the water surface toward the bottom surface of the land farm, and is installed to be rotated by the power generated by the driving motor, and air is blown into the part exposed to the top of the water surface. a tubular rotary shaft having an air inlet hole through which air can be introduced and an air movement path formed so that the air introduced through the air inlet hole can move downward;
It is coupled to the lower end of the tubular rotation shaft in communication with the air movement path, and when the tubular rotation shaft rotates, air is introduced through the air inlet hole and the air movement path and discharged to the lower portion of the water storage space, and the bottom surface of the land farm. An ammonia gas generation reduction device for a land farm, characterized in that it comprises: an impeller generating a swirling flow to suppress the generation of ammonia due to the deposition of foreign substances deposited on the land. The method of claim 1, further comprising a foreign matter discharge unit interlocked with the rotation of the tubular rotating shaft to transport and filter out foreign materials in the lower portion of the water storage space along the extension direction of the tubular rotating shaft,
The foreign matter discharge unit
A feed screw extending spirally along the longitudinal direction on the outer circumferential surface of the tubular rotating shaft, a casing extending along the longitudinal direction of the tubular rotating shaft to surround the screw and fixed to the support unit, and an upper portion of the casing from the casing A discharge pipe extending in a direction in which the outer diameter is expanded and interlocked with the rotation of the tubular rotary shaft to provide a discharge path for the fluid that has risen between the screw and the casing, and to filter out foreign substances contained in the discharged water discharged through the discharge pipe Ammonia gas generation reduction device for land farms, characterized in that it comprises a sieve attached to the discharge pipe or the casing. The upper plate of claim 1, wherein the impeller is fixedly installed at a lower end of the tubular rotation shaft and has a communication hole communicating with the air movement path; a lower plate spaced apart from the upper plate and having a size corresponding to that of the upper plate; And a plurality of wings extending radially between the lower plate and protruding outward more than the upper plate and the lower plate and spaced apart from each other along the circumferential direction of the upper plate Ammonia gas generation for land farms, characterized in that reduction device. The method of claim 1, wherein the tubular rotating shaft is installed to be relatively rotatable and rotates on the water surface of the water stored in the water storage space to stir the water stored in the water storage space and simultaneously to stir the water stored in the water storage space and the surface of the water. An air mixing unit that mixes air to increase the amount of dissolved oxygen in the water stored in the water storage space;
The air mixing unit is installed in contact with the surface of the water at the outer circumferential surface of the tubular rotating shaft and coupled to be relatively rotatable with respect to the tubular rotating shaft with the tubular rotating shaft as a rotation center, and protruding from the rotating hub in the circumferential direction to rotate Ammonia gas generation reduction device for land farms, characterized in that it comprises a plurality of blades that contact the water surface and generate surface waves, and a sub-motor that rotates the rotating hub body through a power transmission element. The support unit of claim 1, wherein the support unit includes floating bodies spaced apart from each other floating in the water stored in the water storage space, bases formed in a plate shape and respectively installed on the floating bodies, and installed on the bases, respectively. Vertical frames extending upwardly, connecting frames interconnecting the vertical frames, guide frames installed on the connecting frames extending in the vertical direction and spaced apart from each other, and being movable in the vertical direction along the guide frames. It is installed and has a motor support part for supporting the drive motor, and a vertical movement part for moving the motor support part in a vertical direction,
The motor support unit protrudes to be positioned between a fixed plate on which the driving motor is fixedly installed, a vertical plate extending upward from an end of the fixed plate in a direction toward the guide frame, and the guide frame in the vertical plate. A pair of protruding plates spaced apart from each other, including a pair of pull-in pieces protruding into the restraining groove formed in the guide frame opposed to the pair of protruding plate materials and moving in the vertical direction along the restraining groove of the guide frame Ammonia gas generation reduction device for land farms, characterized in that.

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