KR20210126530A - Room transportable aquaponics system for shrimp farming - Google Patents

Abstract

The present invention relates to an aquaponics system for compartment transfer to cultivate a shrimp comprising: a water tank which is opened to an upper side and stores water; one or more port beds which are arranged to move in a ring-shaped path in the water tank and include inserting holes for inserting a plant port to be immersed in the water of the water tank; a bed transferring unit which moves each of port beds along the path; a plurality of separating compartments which are circulated and moved along the ring-shaped path inside the water tank, and divide and form a space for cultivating the macrobrachium rosenbergii inside the water tank; and a compartment transferring unit which moves each of separation compartments along the path. According to the present invention, since the port beds in which the plant port is mounted in aquaponics are easily circulated and moved from a cultivating position to a harvesting position, economical cultivation is facilitated through labor cost reduction by decreasing unnecessary movement of a worker and reducing effort and manpower required for harvesting. The present invention reinforces individual cultivation by considering characteristics eating each other; promotes mass cultivating by increasing breeding density despite of the individual cultivation; conveniently performs work necessary for cultivation of the macrobrachium rosenbergii in a predetermined place by facilitating transferring for each compartment which provides the cultivating space; and minimizes effort and the number of people required for the cultivation.

Description

{Room transportable aquaponics system for shrimp farming}

The present invention relates to an aquaponics system capable of transporting a compartment for shrimp culture, and more particularly, by enabling a port bed in which a plant pot is mounted in aquaponics to be easily circulated from a cultivation position to a harvesting position, an operator By reducing the unnecessary movement of prawns, it reduces the effort and manpower required for harvesting, enabling economical cultivation by reducing labor costs, etc. It relates to an aquaponics system capable of transporting a compartment for shrimp farming that enables the transport of each compartment to provide a culture space and to conveniently perform the work required for shrimp farming at a predetermined place.

In general, aquaponics is a compound word of aquaculture and hydroponics, and refers to a method of cultivating and harvesting fish and crops together.

As a conventional technology for aquaponics, the "aquaponics system" of Korean Patent Application Laid-Open No. 10-2018-0123881 has been proposed, which stores a certain level of water to provide a space for aquatic organisms to inhabit. water tank; a cultivation unit coupled to the water tank to be disposed above the water stored in the water tank, and providing a space for plants to inhabit; a circulation unit disposed inside the water tank and supplying water stored inside the water tank to the cultivation unit; and a filter unit disposed inside the water tank unit and filtering suspended matter or oil from the water stored inside the water tank unit. Including, the water stored in the water tank is filtered by the filter unit as the water stored in the water tank flows into the circulation unit due to a difference in water level between the water stored in the water tank and the water stored inside the circulation unit.

However, this prior art needs improvement in that it does not present any technology related to the improvement of the efficiency of cultivation and aquaculture.

On the other hand, the giant prawn, which can be considered as a target of aquaponics, is a freshwater prawn of the genus Shrimp family, which grows in subtropical areas such as Thailand and Taiwan, and is the world's largest freshwater shrimp with a male length of about 40 cm and 400 g. It is popular as a food ingredient and is a major source of income for the fishery industry. Shrimp can grow up to 300-400 g in 6-9 months and have high added value. Due to the recent development and dissemination of aquaculture technology by the National Academy of Fisheries Science, the aquaculture industry is being actively promoted in the domestic fishery.

However, the above-mentioned prior art has a problem that is not suitable for shrimp farming, such as giant spider prawns.

In order to solve the problems of the prior art as described above, the present invention is to reduce unnecessary movement of the operator by allowing the pot bed to which the plant pot is mounted in aquaponics to be easily circulated from the cultivation position to the harvest position, thereby reducing the harvest. It enables economical cultivation by reducing labor costs by reducing the effort and manpower required for production, reinforcing individual aquaculture in consideration of the characteristics of giant prawns eating each other, and increasing the breeding density despite individual farming By promoting aquaculture and making it possible to transport each compartment that provides a culture space, the work necessary for the culture of the black spider shrimp can be conveniently performed at a fixed place, thereby minimizing the effort and manpower required for individual culture. there is a purpose to

Other objects of the present invention will be easily understood through the description of the following embodiments.

In order to achieve the object as described above, according to one aspect of the present invention, it is opened upwardly, a water tank for water storage; a pot bed disposed in plurality so as to be movable in a ring-shaped path on the water tank and having at least one fitting hole for fitting the plant pot to be immersed in the water of the water tank; a bed transfer unit for allowing each of the port beds to move along the path; a separation compartment arranged in plurality to move cyclically along a ring-shaped path from the inside of the tank, and to be submerged in water from the inside of the tank to divide and form a space for aquaculture of giant scallops; and a compartment transfer unit for allowing each of the separation compartments to move along the path.

의 평면 형태를 가지도록 하는 직선저수부; 및 상기 곡률저수부 및 상기 직선저수부의 내측에 상기 베드이송부 및 상기 칸이송부가 수용되도록 마련되는 수용부;를 포함하고, 상기 포트베드는, 상기 곡률저수부와 상기 직선저수부를 따라 이동하도록 설치되고, 상기 곡률저수부의 상단과 상기 직선저수부의 상단을 따라 이동하는 제 1 이동가이드에 의해 이동이 가이드되며, 상기 분리칸은, 상기 곡률저수부와 상기 직선저수부를 따라 이동하도록 설치되고, 상기 곡률저수부의 내측부와 상기 직선저수부의 내측부를 따라 이동하는 제 2 이동가이드에 의해 이동이 가이드될 수 있다.The water tank is located at both ends, respectively, a pair of curvature reservoirs forming a curvature corresponding to a semicircle; It is made in a pair to connect both ends of each of the curvature reservoirs to each other, and together with the curvature reservoir

A straight reservoir to have a planar shape of; and a accommodating part provided to accommodate the bed transfer part and the kan transfer part inside the curvature reservoir and the straight reservoir part, wherein the port bed moves along the curvature reservoir and the straight reservoir part The movement is guided by a first moving guide that moves along the upper end of the curvature reservoir and the upper end of the straight reservoir, and the separation compartment moves along the curvature reservoir and the straight reservoir. The movement may be guided by a second movement guide that is installed and moves along the inner portion of the curvature reservoir and the inner portion of the straight reservoir.

The port bed is made of a rectangular plate-shaped member placed along the width direction in each of the curvature reservoir and the straight reservoir, and a roller or a ball provided as the first movement guide on one bottom surface is the curvature reservoir. The upper end of one side and the upper end of one side of the linear reservoir are rotatably supported, and the other end is connected to the bed transfer unit to move along the curvature reservoir and the straight reservoir, and the separation compartment is the curvature reservoir. and a pair of side plates are placed vertically on each of the straight reservoirs in the width direction, and the space into which the water of the water tank flows is formed between each of the side plates, and the side plates are connected to maintain a distance from each other The connecting plate is provided vertically, and a mesh for blocking the movement of the shrimp is installed on the open upper part, and a roller or ball corresponding to the second movement guide is installed on one side of the inner surface of the curvature reservoir and the straight reservoir. It is provided to be rotatably supported by the guide part provided on the inner surface of the , and the other side is connected to the kan transfer part so as to move along the inside of the curvature reservoir and the inside of the straight reservoir.

The bed transfer unit may include: a first transfer motor installed in the accommodation unit; a first wire sprocket installed at one end of the accommodating part so as to be rotated by the first transfer motor; a second wire sprocket rotatably installed at the other end of the receiving part; a first wire supported by both sides of the first and second wire sprockets to perform endless orbital motion, and fixed to a fixing part of each of the port beds; and the first wire is fixed to the first wire in a plurality along the longitudinal direction to prevent the fixing part of the port bed from slipping from the first wire, and by being caught by the teeth of the rotating first and second wire sprockets, the first wire It may include; a first disk to enable the infinite orbital movement of the.

The compartment transfer unit, a second transfer motor installed in the receiving unit; a third wire sprocket installed at one end of the accommodating part to rotate by the second transfer motor; a fourth wire sprocket rotatably installed at the other end of the receiving part; a second wire supported by both sides of the third and fourth wire sprockets so as to perform endless orbital motion, and fixed to a fixing part of each of the separation compartments; and the second wire is fixed to the second wire in a plurality along the longitudinal direction to prevent the fixing part of the separation compartment from slipping from the second wire, and by being caught by the teeth of the rotating third and fourth wire sprockets, the second wire It may include; a second disk to enable the infinite orbital movement of the.

By connecting a plurality of vertically on both sides of the water tank, the stacking table so that the plurality of water tanks are arranged in multiple stages with a distance from each other; and a light irradiation plate having both sides fixed to the stacking table so as to irradiate light downward for each upper side of the water tank, wherein the bed transfer unit comprises: Installed to perform endless orbital motion by two wire sprockets, each of the port beds is fixed to the first disk wire, and the compartment transfer unit includes a second disk wire located below the first disk wire. It is installed to perform endless orbital motion by the third and fourth wire sprockets by driving the transfer motor, and each of the third and fourth wire sprockets is located below each of the first and second sprocket wires, but the first and the first and third rotation shafts of each of the third wire sprockets may be installed to overlap each other to form concentricity, and the second and fourth rotation shafts of the second and fourth wire sprockets may be installed to overlap each other to form concentricity. .

According to the aquaponics system capable of transferring compartments for shrimp culture according to the present invention, the pot bed in which the plant pot is mounted in the aquaponics can be easily circulated from the cultivation position to the harvest position, thereby reducing unnecessary movement of the operator. By reducing the effort and manpower required for harvesting, economical cultivation is possible through labor cost reduction, etc., and taking into account the characteristics of giant prawns eating each other, individual aquaculture can be strengthened. By increasing the density, it is possible to promote mass culture, and by making it possible to transport each compartment that provides a culture space, the work necessary for the culture of the giant shrimp can be conveniently performed at a fixed place, which in turn makes it possible to carry out individual cultured shrimp. It has the effect of minimizing the effort and manpower required for aquaculture.

1 is a side view showing an aquaponics system capable of transporting a compartment for shrimp culture according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line AA of FIG. 1 , and is a plan view of the pot bed.
Figure 3 is an enlarged perspective view showing the main part of the port bed of the aquaponics system capable of transporting a compartment for shrimp culture according to an embodiment of the present invention.
FIG. 4 is a cross-sectional view taken along line BB of FIG. 1 , and is a plan cross-sectional view showing a separation compartment.
5 is a front cross-sectional view showing the main part of the aquaponics system capable of transporting a compartment for shrimp culture according to an embodiment of the present invention.
6 is a side cross-sectional view showing the main part of an aquaponics system capable of transporting a compartment for shrimp culture according to an embodiment of the present invention.
7 is a side view showing a bed transport unit and a compartment transport unit of the aquaponics system capable of transporting compartments for shrimp culture according to an embodiment of the present invention.
8 is a plan view showing an aquaponics system capable of transporting a compartment for shrimp culture according to another embodiment of the present invention.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to a specific embodiment, it should be understood as including all changes, equivalents or substitutes included in the spirit and scope of the present invention, and may be modified in various other forms. and the scope of the present invention is not limited to the following examples.

Hereinafter, an embodiment according to the present invention will be described in detail with reference to the accompanying drawings, and the same reference numerals are assigned to the same or corresponding components regardless of reference numerals, and redundant description thereof will be omitted.

1 is a side view showing an aquaponics system capable of transporting a compartment for shrimp culture according to an embodiment of the present invention.

Referring to FIG. 1 , the aquaponics system 100 capable of transferring a compartment for shrimp farming according to an embodiment of the present invention includes a water tank 110 , a pot bed 120 , and a bed transfer unit 130 (see FIG. 7 ). , a separation compartment 140 (see FIG. 4) and a compartment transfer unit 150 (see FIG. 7).

1, 2 and 4, the water tank 110 is opened upward, and as for water storage, water for hydroponic cultivation and shrimp culture is stored. Fresh water is stored taking into account points and hydroponics.

의 평면 형태를 가지도록 하는 직선저수부(112)와, 곡률저수부(111) 및 직선저수부(112)의 내측에 베드이송부(130)와 칸이송부(150)가 수용되도록 마련되는 수용부(113)를 포함할 수 있다. 따라서, 수조(110)는 저수부(111,112) 구조가 수경 재배를 위한 포트베드(120)와 새우 양식을 위한 분리칸(140)의 위치를 순환 이동시킬 수 있도록 하는 형태를 가진다.The water tank 110 is located at both ends, and consists of a pair of curvature reservoirs 111 forming a curvature corresponding to a semicircle, and a pair of curvature reservoirs 111 to connect both ends of each of the curvature reservoirs to each other. with the hand (111)

A receiving part provided to accommodate the bed transfer unit 130 and the compartment transfer unit 150 on the inside of the straight reservoir 112 and the curvature reservoir 111 and the straight reservoir 112 to have a flat shape of (113) may be included. Accordingly, the water tank 110 has a shape such that the water storage units 111 and 112 structures can circulate the positions of the pot bed 120 for hydroponic cultivation and the separation compartment 140 for shrimp culture.

Referring to FIGS. 2, 3, 5 and 6 , the pot bed 120 is arranged in plurality to move a ring-shaped path on the water tank 110 , and the plant pot 10 is the water tank 110 . At least one fitting hole 121 to be fitted so as to be submerged in water is formed. Here, the plant pot 10 may be configured to grow only one plant, and a plurality of openings 12 for contact with water or nutrient solution may be formed on the bottom as well as the side. In addition, the plant pot 10 may be formed with a locking part 11 on the upper edge so as to be caught while being inserted into the fitting hole 121 . The plant is a plant that can be grown hydroponically, and may be a plant that can be grown individually, such as green vegetables or strawberries.

The pot bed 120 may be installed to move along the curvature reservoir 111 and the straight reservoir 112, and move along the upper end of the curvature reservoir 111 and the upper end of the straight reservoir 112. 1 Movement may be guided by the movement guide 123 .

The pot bed 120 may be formed of a rectangular plate-shaped member placed along the width direction in each of the curvature reservoir 111 and the straight reservoir 112, and a roller provided as a first moving guide 123 on one bottom surface. The ball is rotatably supported on the upper end of one side of the curvature reservoir 111 and the upper end of one side of the straight reservoir 112, and the other end is connected to the bed transfer unit 130 to the curvature reservoir 111 and the straight reservoir. It can be moved along (112). The pot bed 120 is made of a pair of fixing parts 122 on the other side, and is disposed on both sides of the disk 139, which will be described later, therebetween. .

The bed transfer unit 130 allows each of the port beds 120 to move along the above-described path. The bed transfer unit 130 is, for example, installed at one end of the accommodation unit 113 to rotate by the first transfer motor 131 and the first transfer motor 131 installed in the accommodation unit 113, as in this embodiment. The first wire sprocket 136, the second wire sprocket 137 rotatably installed at the other end of the receiving part 113, and the first and second wire sprockets 136 and 137 are supported by both sides to perform endless orbital motion. The first wire 138 fixed to the fixing part 122 of each of the port bed 120 and the first wire 138 are fixed in a plurality along the longitudinal direction to the fixing part of the port bed 120 . It is possible to prevent the 122 from slipping from the first wire 138, and by being caught on the teeth (not shown) of the rotating first and second wire sprockets 136 and 137, the It may include a first disk 139 to enable the caterpillar movement. Here, the first wire 138 and the first disk 139 may constitute the first disk wires 138 and 139 .

In the first transfer motor 131 , a first driving sprocket 132 provided on the rotating shaft is a first driven sprocket provided on the first rotating shaft 135 of the first wire sprocket 136 through the first driving chain 133 . By being connected to 134 , the rotational force can be transmitted to the first wire sprocket 136 through the first driving sprocket 132 , the first driving chain 133 and the first driven sprocket 134 . A rotational force may be provided to the first wire sprocket 136 by using various gear assemblies, reduction gears, or the like without doing so. In addition, the first transfer motor 131 and the first rotation shaft 135 may be installed on the mounting table 114 provided in the receiving part 113 .

Separation compartment 140 is arranged in plurality to move cyclically along a ring-shaped path inside the water tank 110, and is submerged in water from the inside of the water tank 110 to provide a space for aquaculture of shrimps, such as prawns. to form a division.

Separation compartment 140 may be installed to move along the curvature reservoir 111 and the straight reservoir 112, and move along the inner part of the curvature reservoir 111 and the inner part of the straight reservoir 112. 2 The movement may be guided by the movement guide 144 . Accordingly, the separation compartment 140 is movable along the inside of the curvature reservoir 111 and the straight reservoir 112 by the second movement guide 144 and the compartment transfer unit 150 .

The separation compartment 140 may include a pair of side plates 141 in each of the curvature reservoir 111 and the straight reservoir 112, vertically placed in the width direction, and the water tank 110 between each of the side plates 141. It is possible to form the space through which the water is introduced, and the connecting plate 142 connected to each of the side plates 141 to maintain a distance from each other may be provided vertically, and to block the movement of the shrimp in the open upper part. A mesh 145 for this may be installed, and a roller or ball corresponding to the second movement guide 144 on one side is provided on the inner surface of the curvature reservoir 111 and the inner surface of the straight reservoir 112 It may be provided to be rotatably supported by the guide part 115 , and the other side is connected to the kan transfer part 150 to move along the inside of the curvature reservoir 111 and the inside of the straight reservoir 112 . . The mesh 145 may be detachably installed from the separation compartment 140 by a locking structure or a fitting structure.

Separation compartment 140 may be connected so that the side plate 141 and the connecting plate 142 have a U-shaped planar shape with each other. They may be connected to each other, and further, a partition plate 146 parallel to the connecting plate 142 may be provided to vertically intersect between the side plates 141 so as to divide the inner space. In addition, the partition plate 146 may increase the number of aquaculture spaces in the separation compartment 140 by increasing the number.

The compartment transfer unit 150 allows each of the separation compartments 140 to move along the above path, and may have various configurations for this purpose. A plurality of fixed second disk wires 158 and 159 may be used. In this way, by the ring-shaped circulation movement of the separation compartment 140 by the compartment transfer unit 150, it is possible to facilitate the observation, import and export of all shrimp, for example, giant scallop shrimp, without the need for an operator to move in a predetermined place. have.

The kan transfer unit 150 is, for example, a second transfer motor 151 installed in the accommodating part 113 and a third wire installed at one end of the accommodating part 113 to rotate by the second transfer motor 151 . The sprocket 156, the fourth wire sprocket 157 rotatably installed at the other end of the accommodating part 113, and the third and fourth wire sprockets 156 and 157 are supported on both sides to perform endless orbital motion, and are separated. A second wire 158 fixed to the second fixing part 143 of each compartment 140, and a plurality of second wires 158 fixed along the longitudinal direction to the second fixing part of the separation compartment 140 A second disk that prevents the second wire 158 from slipping, and enables the endless orbital movement of the second wire 158 by being caught on the teeth of the rotating third and fourth wire sprockets 156 and 157. (159).

The second conveying motor 151 is a second driven sprocket in which a second driving sprocket 152 provided on the rotating shaft is provided on the third rotating shaft 155 of the third wire sprocket 156 through the second driving chain 153 . By being connected to (154), the rotational force can be transmitted to the third wire sprocket 156 through the second driving sprocket 152, the second driving chain 153, and the second driven sprocket 154. A rotational force may be provided to the third wire sprocket 156 by using various gear assemblies, reduction gears, or the like without doing so. In addition, the second fixing part 143 of the separation compartment 140 is formed as a pair and is disposed on both sides of the second disk 159 with the second disk 159 therebetween so as to be fitted into the second wire 158 in the form of a groove or a hole, respectively. can do.

As described above, the bed transfer unit 130 may be installed such that the first disk wires 138 and 139 perform endless orbital motion by the first and second wire sprockets 136 and 137 by the driving of the first transfer motor 131. , Each of the port bed 120 may be fixed to the first disk wire (138, 139).

In the Kan transfer unit 150, the second disk wires 158 and 159 located below the first disk wires 138 and 139 are driven by the second transfer motor 151 and are infinite by the third and fourth wire sprockets 156 and 157. It may be installed to perform orbital motion, and the third and fourth wire sprockets 156 and 157 are respectively located below the first and second sprocket wires 136 and 137, respectively, and the first and third wire sprockets 136 and 156 respectively. The first and third rotation shafts 135 and 155 may be installed to overlap each other so as to form concentricity, and the second and fourth rotation shafts 137a and 157a of the second and fourth wire sprockets 137 and 157 respectively overlap each other to form concentricity. It can be installed to Therefore, the space transfer unit 150 and the bed transfer unit 130 can reduce the installation space as much as possible without interfering with each other.

Referring to FIG. 1 , an aquaponics system 100 capable of transporting a compartment for shrimp farming according to an embodiment of the present invention is vertically connected to a plurality of both sides of the water tank 110, so that the water tank 110 is A plurality of stacking tables 160 to be arranged in multiple stages with a distance from each other, and a light irradiation plate 170 having both sides fixed to the stacking table 160 so as to irradiate light downward for each upper side of the water tank 110 is further included. can do. Here, the light irradiation plate 170 may be provided with a plurality of LEDs for irradiating light downward on the bottom surface, thereby providing light necessary for growth to plants. The stacking table 160 may be connected or fixed to the water tank 110 and the light irradiation plate 170 by bolting, welding, or riveting.

In the aquaponics system 100 capable of transporting a compartment for shrimp farming according to an embodiment of the present invention, the operation unit for performing a predetermined operation according to the operation signal by the bed transfer unit 130 and the compartment transfer unit 150 is the outside. can be provided in

8 is a plan view showing an aquaponics system capable of transporting a compartment for shrimp culture according to another embodiment of the present invention.

Referring to FIG. 8 , an aquaponics system 200 capable of transporting a compartment for shrimp farming according to another embodiment of the present invention is an aquaponics system capable of transporting a compartment for shrimp farming according to an embodiment of the present invention. Same as (100), but by configuring the first wire sprocket and the second wire sprocket of the bed transfer part, and the third wire sprocket 256 and the fourth wire sprocket 257 of the can transfer part in plurality, the water tank 210 ) It is possible to increase the number of port beds and separation compartments 240 located on both sides, and thereby, by increasing the number of port beds and separation compartments 240 staying in the working position, it can contribute to increasing work efficiency and , it is possible to facilitate maintenance and management by making it easy for the operator to enter the accommodation unit.

According to the aquaponics system capable of transporting a compartment for shrimp culture according to the present invention, the pot bed in which the plant pot is mounted in the aquaponics can be easily circulated from the cultivation position to the harvest position, so that the operator is not required to It enables economical cultivation by reducing labor costs by reducing the effort and manpower required for harvesting by reducing movement.

In addition, according to the present invention, in consideration of the characteristics of the black spider prawns eating each other, individual culture can be strengthened, and mass culture can be promoted by increasing the breeding density despite individual culture, and each compartment providing a culture space By enabling the transfer, the work necessary for the culture of the black spider prawns can be conveniently performed at a fixed place, thereby minimizing the effort and manpower required for the shrimp culture that requires individual culture.

As described above, the present invention has been described with reference to the accompanying drawings, but it goes without saying that various modifications and variations may be made within the scope without departing from the spirit of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the following claims as well as the claims and equivalents.

110: water tank 111: curvature reservoir
112: straight water reservoir 113: receiving section
114: mounting base 115: guide part
120: port bed 121: fitting hole
122: first fixing part 123: first moving guide
130: bed transfer unit 131: first transfer motor
132: first drive sprocket 133: first drive chain
134,234: first driven sprocket 135: first rotating shaft
136: first wire sprocket 137: second wire sprocket
137a: second axis of rotation 138: first wire
139: first disk 140: separation compartment
141: side plate 142: connecting plate
143: second fixing part 144: second movement guide
145: mesh 146: partition plate
150: kan transfer unit 151: second transfer motor
152: second drive sprocket 153: second drive chain
154: second driven sprocket 155: third rotation shaft
156: third wire sprocket 157: fourth wire sprocket
157a: fourth rotation shaft 158: second wire
159: second disk 160: stacking table
170: light irradiation plate

Claims (6)

an upwardly open, water tank for water storage;
a pot bed disposed in plurality so as to be movable in a ring-shaped path on the water tank and having at least one fitting hole for fitting the plant pot to be immersed in the water of the water tank;
a bed transfer unit for allowing each of the port beds to move along the path;
a separation compartment arranged in plurality to move cyclically along a ring-shaped path from the inside of the tank, and to be submerged in water from the inside of the tank to divide and form a space for aquaculture of giant scallops; and
a compartment transfer unit for allowing each of the separation compartments to move along the path;
Including, an aquaponics system capable of transporting compartments for shrimp farming. The method according to claim 1,
The water tank is
a pair of curvature reservoirs respectively located at both ends and forming a curvature corresponding to a semicircle;
It is made in a pair to connect both ends of each of the curvature reservoirs to each other, and together with the curvature reservoir

A straight reservoir to have a planar shape of; and
Containing; and a receiving portion provided to accommodate the bed transfer unit and the compartment transfer unit inside the curvature reservoir and the straight reservoir.
The port bed,
It is installed to move along the curvature reservoir and the straight reservoir, and the movement is guided by a first moving guide that moves along the upper end of the curvature reservoir and the upper end of the straight reservoir,
The separation compartment is
It is installed to move along the curvature reservoir and the straight reservoir, and the movement is guided by a second moving guide that moves along the inner side of the curvature reservoir and the inner side of the straight reservoir. The aquaponics system that can do this. 3. The method according to claim 2,
The port bed,
It consists of a rectangular plate-shaped member placed in each of the curvature reservoir and the straight reservoir in the width direction, and a roller or ball provided as the first movement guide on one bottom surface is the upper end of one side of the curvature reservoir and the straight line It is rotatably supported on the upper end of one side of the reservoir, and the other side is connected to the bed transfer unit to move along the curvature reservoir and the straight reservoir,
The separation compartment is
A pair of side plates are placed vertically on each of the curvature reservoir and the straight reservoir in the width direction, and the space into which the water of the water tank flows is formed between each of the side plates, and each of the side plates is spaced from each other A connecting plate that is connected to maintain is provided vertically, a mesh for blocking the movement of the shrimp is installed in the open upper part, and a roller or ball corresponding to the second movement guide is installed on one side of the inner surface of the curvature reservoir and It is provided to be rotatably supported by the guide unit provided on the inner surface of the straight reservoir, and the other side is connected to the kan transfer unit to move along the inside of the curvature reservoir and the inside of the straight reservoir, shrimp culture An aquaponics system that can transport compartments for 3. The method according to claim 2,
The bed transfer unit,
a first transfer motor installed in the accommodating part;
a first wire sprocket installed at one end of the accommodating part so as to be rotated by the first transfer motor;
a second wire sprocket rotatably installed at the other end of the receiving part;
a first wire supported by both sides of the first and second wire sprockets to perform endless orbital motion, and fixed to a fixing part of each of the port beds; and
A plurality of fixed portions of the port bed are fixed along the longitudinal direction to the first wire to prevent slipping from the first wire, and by being caught by the teeth of the rotating first and second wire sprockets, the first wire a first disk to enable endless orbital movement;
Including, an aquaponics system capable of transporting compartments for shrimp farming. 3. The method according to claim 2,
The Kan transfer unit,
a second transfer motor installed in the receiving unit;
a third wire sprocket installed at one end of the accommodating part to rotate by the second transfer motor;
a fourth wire sprocket rotatably installed at the other end of the receiving part;
a second wire supported by both sides of the third and fourth wire sprockets so as to perform endless orbital motion, and fixed to a fixing part of each of the separation compartments; and
The second wire is fixed in plurality along the longitudinal direction to prevent the fixing part of the separation compartment from slipping from the second wire, and by being caught by the teeth of the rotating third and fourth wire sprockets, the second wire a second disk to enable endless orbital movement;
Including, an aquaponics system capable of transporting compartments for shrimp farming. 6. The method according to any one of claims 1 to 5,
By connecting a plurality of vertically on both sides of the water tank, the stacking table so that the plurality of water tanks are arranged in multiple stages with a distance from each other; and
It further comprises;
The bed transfer unit,
A first disk wire is installed to perform endless orbital motion by the first and second wire sprockets by driving the first transfer motor, and each of the port beds is fixed to the first disk wire,
The Kan transfer unit,
A second disk wire located below the first disk wire is installed to perform endless orbital motion by third and fourth wire sprockets by driving a second transfer motor, and each of the third and fourth wire sprockets is The first and second sprocket wires are located under each of the wires, and are installed to overlap each other so that the first and third rotation axes of the first and third wire sprockets are concentric with each other, and the second and fourth wire sprockets respectively An aquaponics system capable of transporting a compartment for shrimp farming, which is installed to overlap each other so that the second and fourth rotational axes are concentric.

Images