KR20240003484A - farm structure - Google Patents

Abstract

The present invention relates to a new fish farm structure that allows fish to be raised in natural conditions without causing environmental pollution because there is no need to supply separate feed.
According to the fish farm structure according to the present invention, the water flowing along the river (1) is supplied to the fish farm main body (10) through the water supply channel (20), and the first aquaculture unit (13) and the first submerged unit (14) After sequentially passing through the second aquaculture unit 15 and the second submergence unit 16, it is discharged into the river 1 through the drainage channel 30.
Therefore, not only are the various nutrients and food contained in the water of the river 1 naturally supplied to the fish, so there is no need to feed them separately, but also new water is continuously supplied to the fish farm main body 10, resulting in contamination by food. There is an advantage in that this does not occur.

Description

Farm structure {farm structure}

The present invention relates to a new fish farm structure that allows fish to be raised in natural conditions without causing environmental pollution because there is no need to supply separate feed.

In general, the farm used to raise freshwater fish consists of a concrete tank or a lake dug out of the ground, and the manager must continuously feed the fish while filling the inside with fresh water at a certain level. .

However, in this case, not only is a large amount of water consumed, but the cost increases as a large amount of food is input, and contamination by the food occurs.

In addition, such farms raise fish in an artificial environment, which causes the problem that the quality of fish is lower than that of natural fish.

Therefore, a new method to solve these problems has become necessary.

Registered Patent No. 10-2371691,

The present invention is intended to solve the above problems, and its purpose is to provide a new fish farm structure that allows fish to be raised in natural conditions without causing environmental pollution because there is no need to supply separate feed.

The present invention for achieving the above object includes a fish farm main body 10, which is concavely formed downward on the ground so as to be close to the river 1 and has a water inlet 11 and a drain 12 on the up and downstream sides, and the river ( 1) branched from the water supply channel 20 connected to the water supply port 11 of the fish farm main body 10, and a drainage channel 30 connecting the drain 12 of the fish farm main body 10 and the river 1. It includes a plurality of dams 17 in the middle part of the fish farm main body 10, so that the internal space of the fish farm main body 10 includes the upstream first culture unit 13 and the first culture unit ( A first submerged portion 14 located downstream of 13), a second submerged portion 15 located downstream of the first submerged portion 14, and located downstream of the second submerged portion 15. It is divided into a second submerged portion 16, and a fish farm structure is provided in which a passage 17a for water and fish to pass through is formed in the dam 17.

According to another feature of the present invention, aquatic plants are planted inside the first and second submerged portions 14 and 16, and the water passing through the first and second submerged portions 14 and 16 is caused by the aquatic plants. A fish farm structure is provided, characterized in that the suspended solids contained therein are filtered.

According to another feature of the present invention, the drain 12 of the fish farm main body 10 combines drain pipes 11c and 11d so as to penetrate the dam 17 installed to block the inlet portion of the drain 30 in the up and down direction. A fish farm structure is provided, wherein a net (11b) is coupled to the ends of the drain pipes (11c, 11d).

According to another feature of the present invention, a fish farm structure is provided, wherein the water supply channel 20 is provided with a water supply gate 21 that controls the flow rate of water flowing in through the water supply channel 20.

According to another feature of the present invention, it further includes a waterproof fence 40 provided on the circumference of the fish farm main body 10, and the waterproof fence 40 is a support provided on the circumference of the fish farm main body 10 ( 41), and a tarpaulin 42 fixed to the support 41 and having its lower end embedded in the upper surface of the circumference of the fish farm main body 10.

According to another feature of the present invention, a plurality of soil height measuring means 50 provided inside the first form part 13 and measuring the height of the soil accumulated on the bottom surface of the first form part 13; , It is installed to penetrate the embankment 17 so as to extend from the first culture unit 13 to the inside of the second culture unit 15, and the soil accumulated on the bottom surface of the first culture unit 13 is transferred to the second culture unit 15. It further includes a plurality of discharge means (70) discharging to the part (15), and a control means (80) that receives a signal from the soil and sand height measuring means and controls the operation of the discharge means (70), and the soil and sand height The measuring means 50 includes a lifting guide 51 provided to extend upward on the bottom surface of the first form part 13, a lifting platform 52 coupled to the lifting guide 51, and A cylinder mechanism 53 is connected to the elevating platform 52 and raises and lowers the elevating platform 52, a contact plate 54 is coupled to the lower side of the elevating platform 52 to enable elevation, and is provided on the elevating platform 52. The platform includes a rise detection means 55 that detects when the gap between the platform 52 and the contact plate 54 narrows, and a height detection device 56 that measures the raised height of the platform 52. As (52) is lowered, the contact plate 54 touches the upper surface of the soil accumulated on the bottom surface of the first form part 13, and when the rise detection means 55 detects this, the height detection means 56 It is configured to measure the height of the soil by measuring the height of the lifting platform 52, and the discharge means 70 extends from the first culture unit 13 to the inside of the second culture unit 15. It includes a discharge pipe 71 installed to penetrate the embankment 17 and a control valve 72 provided in the middle of the discharge pipe 71, and the upstream end of the discharge pipe 71 is each equipped with different soil height measurement means. It is arranged close to (50), and the control means (80) receives a signal from the soil height measuring means (50) and determines whether the soil is on the bottom surface of the first form part (13) to any one of the soil height measuring means. When accumulation is detected, the control valve 72 provided in the discharge means 70 extended to approach the corresponding soil height measuring means 50 is opened, and the soil along with the water inside the first culture unit 13 is discharged through the discharge pipe. A fish farm structure is provided, characterized in that it is discharged into the second aquaculture unit 15 through (71).

According to the fish farm structure according to the present invention, the water flowing along the river (1) is supplied to the fish farm main body (10) through the water supply channel (20), and the first aquaculture unit (13) and the first submerged unit (14) After sequentially passing through the second aquaculture unit 15 and the second submergence unit 16, it is discharged into the river 1 through the drainage channel 30.

Therefore, not only are the various nutrients and food contained in the water of the river 1 naturally supplied to the fish, so there is no need to feed them separately, but also new water is continuously supplied to the fish farm main body 10, resulting in contamination by food. There is an advantage in that this does not occur.

1 is a plan view showing the structure of a fish farm according to the present invention;
Figure 2 is a side cross-sectional view of the fish farm structure according to the present invention,
Figure 3 is a front view showing the drain of the fish farm structure according to the present invention;
Figure 4 is a side cross-sectional view showing a second embodiment of the fish farm structure according to the present invention;
Figure 5 is an enlarged side cross-sectional view showing the main part of the second embodiment of the fish farm structure according to the present invention;
Figure 6 is a block diagram of a second embodiment of the fish farm structure according to the present invention;
Figures 7 and 8 are side cross-sectional views showing the operation of the second embodiment of the fish farm structure according to the present invention.

Hereinafter, the present invention will be described in detail based on the attached illustration drawings.

Figures 1 to 3 show the structure of the fish farm according to the present invention. The fish farm main body (10) is formed concave downward on the ground to be close to the river (1) and has a water supply port (11) and a drain port (12) on the up and downstream sides. ), a water supply path (20) branched from the river (1) and connected to the water supply port (11) of the fish farm main body (10), and a drain port (12) of the fish farm main body (10) connected to the river (1). It consists of a drainage channel (30) and a waterproof fence (40) provided around the circumference of the fish farm main body (10), so that water flowing in the river (1) flows upstream of the fish farm main body (10) through the water supply channel (20). After being supplied to the side, it is discharged into the river (1) through the drainage channel (30).

At this time, a river bank 2 is installed in the middle of the river 1, and the water level upstream of the river bank 2 is maintained higher than that downstream.

The fish farm main body 10 is formed on one side of the river 1 to extend parallel to the river 1, using a naturally formed puddle on one side of the river 1, or artificially formed in the river 1. The flat part can be formed by excavating it into an appropriate shape.

At this time, the fish farm main body 10 is preferably configured in a triangular shape with a narrow width on the upstream side and a wide width on the downstream side.

In addition, the bottom surface of the fish farm main body 10 is configured to become lower toward the downstream.

In addition, a plurality of dams 17 are provided in the middle part of the fish farm main body 10, so that the internal space of the fish farm main body 10 is divided into the upstream first culture unit 13 and the first culture unit 13. ), a first submerged portion 14 located on the downstream side, a second submerged portion 15 located downstream of the first submerged portion 14, and a second submerged portion 15 located downstream of the second submerged portion 15. It is divided into a second submerged portion (16).

The dam 17 extends laterally inside the fish farm main body 10 and is constructed by piling up soil or constructing a concrete retaining wall to block the fish farm main body 10, and has a middle portion for water and fish to pass through. A passage 17a is formed.

The passage (17a) is formed concave downward on the upper surface of the dam 17, so that when the level of water stored inside the fish farm main body 10 is sufficient, water and fish move downstream or upstream through the passage (17a). I do it.

The first and second aquaculture units 13 and 15 are spaces for cultivating fish inside.

The first and second submerged portions 14 and 16 are spaces for purifying water that has passed through the first and second aquaculture portions 13 and 15.

For this purpose, water plants are planted inside the first and second submerged portions 14 and 16.

The aquatic plants can be used as various types of perennial aquatic plants, including crucian carp and cattails.

Accordingly, as the water stored in the first and second submerged portions 14 and 16 passes through the water weeds, various contaminants, including suspended solids, contained in the water are filtered out.

Meanwhile, the first and second submerged portions 14 and 16 function to provide an environment in which fish can grow, in addition to purifying water using aquatic plants.

That is, water plants grow in the first and second submerged parts 14 and 16, providing a hiding space for young or small fish, etc., so that they can grow safely.

The drain 12 is constructed by combining drain pipes 11c and 11d so as to pass through a dam 17 installed to block the entrance portion of the drain 30 in the up and down direction.

At this time, as shown in FIG. 3, the drain pipes 11c and 11d are composed of an external pipe 11c with a large diameter and a smaller diameter than the external pipe 11c, and are located inside the external pipe 11c. It consists of a plurality of combined inner tubes (11d).

In addition, a net (11b) is coupled to the downstream ends of the drain pipes (11c, 11d) to prevent fish cultured in the fish farm main body (10) from escaping into the river (1) through the drain (12).

In addition, a net (11b), not shown, is disposed on the upper part of the fish farm main body 10 to protect fish from algae.

Meanwhile, the fish farm main body 10 is equipped with a water supply means (not shown) for supplying groundwater, and when the water level of the fish farm main body 10 decreases in the dry season, ground water is supplied to the fish farm main body 10 using the water supply means. , to prevent the water level of the fish farm main body 10 from lowering.

The water supply channel (20) uses a water pipe made of concrete, and connects the upstream of the river bank (2) in the river (1) with the water supply port (11) so that water from the river (1) flows into the fish farm main body (10). ensure that it is supplied.

At this time, the water supply passage 20 is provided with a water supply gate 21 to control the flow rate of water flowing through the water supply passage 20.

The water supply gate 21 uses a manual water gate that is manually operated by an administrator.

The drain 30 is configured in the form of a waterway with an open upper surface, so that water discharged through the drain 12 is drained from the river 1 toward the downstream side of the river bank 2.

The waterproof fence 40 includes a support 41 provided on the circumference of the fish farm main body 10, and a tarpaulin fixed to the support 41 so that the lower end is embedded in the upper surface of the circumference of the fish farm main body 10. 42).

The support 41 is made of a high-strength metal material.

The tarpaulin 42 is made of a high-strength synthetic water-based material, and when external animals penetrate into the inside of the fish farm main body 10, or when rain falls or a flood occurs, external water flows into the fish farm main body 10. prevent it from happening.

At this time, an electric shock wire is provided on the outer circumferential surface of the tarp 42, so that when an animal touches the tarp 42, the animal is electrocuted, thereby preventing the animal from damaging the tarp 42.

According to the fish farm structure configured in this way, the water flowing along the river 1 is supplied to the fish farm main body 10 through the water supply channel 20, and the first aquaculture unit 13 and the first submerged unit 14 After sequentially passing through the second aquaculture unit 15 and the second submergence unit 16, it is discharged into the river 1 through the drainage channel 30.

Therefore, not only are the various nutrients and food contained in the water of the river 1 naturally supplied to the fish, so there is no need to feed them separately, but also new water is continuously supplied to the fish farm main body 10, resulting in contamination by food. There is an advantage in that this does not occur.

In addition, water plants are planted inside the first and second submerged parts 14 and 16, and suspended matter contained in the water passing through the first and second submerged parts 14 and 16 is filtered by the water plants. , there is an advantage of being able to purify the water discharged to the second aquaculture unit (15) and the river (1).

In addition, the drain 12 of the fish farm main body 10 is configured by combining drain pipes 11c and 11d so as to penetrate the dam 17 installed to block the entrance portion of the drain 30 in the up and down direction, and the drain pipe ( Since the net 11b is coupled to the ends of 11c and 11d), there is an advantage in effectively preventing fish cultured in the fish farm main body 10 from escaping into the river 1 through the drain 12.

In addition, the water supply channel 20 is provided with a water supply gate 21 that controls the flow rate of water flowing in through the water supply channel 20, so that depending on the water level of the river 1, the water supplied to the fish farm main body 10 By controlling the flow rate, there is an advantage in preventing the water level inside the fish farm main body 10 from increasing excessively.

In addition, a waterproof fence 40 is provided around the circumference of the fish farm main body 10, and the waterproof fence 40 includes a support 41 provided around the circumference of the fish farm main body 10, and the support 41. It consists of a tarpaulin (42) fixed to the bottom of the fish farm main body (10) so that it is embedded in the upper surface of the fish farm main body (10), which not only protects the fish by preventing animals from penetrating into the fish farm main body (10), but also protects the fish from rainwater. It is possible to prevent the water level of the fish farm main body 10 from flowing into the fish farm main body 10 and increasing excessively, or from turbid rainwater flowing into the fish farm main body 10, thereby increasing the turbidity of the water stored in the fish farm main body 10. There is an advantage.

4 to 8 show another embodiment of the present invention, and a plurality of devices are provided inside the first form part 13 to measure the height of soil accumulated on the bottom surface of the first form part 13. A soil height measuring means (50) is installed to penetrate the embankment (17) so as to extend from the first form part (13) to the inside of the second form part (15), and is installed on the bottom surface of the first form part (13). A plurality of discharge means (70) for discharging the soil accumulated in the soil and sand to the second form part (15), and a control means (80) for receiving a signal from the soil and sand height measurement means and controlling the operation of the discharge means (70). This is further provided.

As shown in FIG. 5, the soil height measuring means 50 includes a lifting guide 51 provided to extend upward on the bottom surface of the first form part 13, and is lifted and lowered by the lifting guide 51. A lifting platform 52 that is movably coupled, a cylinder mechanism 53 that is connected to the lifting platform 52 and raises and lowers the elevator platform 52, and a contact plate 54 that is movably coupled to the lower side of the lifting platform 52. ), a rise detection means 55 provided on the elevating platform 52 and detecting when the contact plate 54 is raised, and a height detection means 56 measuring the raised height of the elevating platform 52. do.

The lifting guide 51 extends in the vertical direction and has a square bar shape with its lower end embedded and fixed to the bottom surface of the first form part 13.

The lifting platform 52 has a guide hole 52a formed at one end through which the lifting guide 51 passes in the vertical direction, and an extension bar 52b extending downward is formed at the lower side of the other side.

The cylinder mechanism 53 uses an air cylinder whose upper end is fixed to the lifting guide 51 and whose piston rod extending downward is connected to the lifting table 52 so that the lifting board 52 is lowered when extended.

The contact plate 54 is coupled to the extension bar 52b to be able to be lifted.

The rising detection means 55 is embedded in the lower side of the lifting platform 52 and uses a limit switch provided with a push button 55a protruding downward.

The height sensing means 56 is connected to the elevating platform 52 and uses a linear scale to measure the height of the elevating platform 52 in real time.

Therefore, when the lifting platform 52 is raised and the lifting platform 52 is lowered using the cylinder mechanism 53, as shown in FIG. 7, the contact plate 54 is lowered together.

And, when the contact plate 54 is in close contact with the upper part of the soil that has sunk to the bottom of the first form part 13, the contact plate 54 is no longer lowered and only the lifting platform 52 is lowered, so the lifting platform ( The gap between 52) and the contact plate 54 becomes narrow.

Accordingly, the lifting platform 52 presses the push button 55a of the rising detection means 55.

And, at the moment when the push button 55a is pressed, the height of the elevating platform 52 is measured using the rise detection means 55, so that the height of the soil, that is, the bottom of the first culture unit 13, is measured. The height from the top of the soil to the top of the soil can be measured.

The discharge means 70 includes a discharge pipe 71 installed to penetrate the embankment 17 so as to extend from the first culture unit 13 to the inside of the second culture unit 15, and a middle of the discharge pipe 71. It consists of a control valve 72 provided in the unit.

At this time, the upstream end of the discharge pipe 71 is arranged to be close to each different soil height measurement means 50, and the middle part of the discharge pipe 71 is arranged to penetrate the embankment 17, and the discharge pipe 71 The downstream end extends to the inner downstream side of the second form part 15 so as to be located lower than the upstream end of the discharge pipe 71.

The control valve 72 operates under the control of the control means 80 and uses a solenoid valve to open and close the middle portion of the discharge pipe 71.

The control means 80 receives a signal from the soil height measuring means 50, and when any one of the soil height measuring means detects that soil has accumulated on the bottom surface of the first form part 13 above the reference height, The control valve 72 provided in the discharge means 70 extended to approach the soil height measurement means 50 is opened.

When the control valve 72 of the discharge means 70 is opened in this way, as shown in FIG. 8, the water stored in the first aquaculture unit 13 flows to the second aquaculture unit 15 through the discharge pipe 71. As it is discharged, the soil that has settled nearby is drawn in and discharged into the second culture unit (15) through the discharge pipe (71).

According to the fish farm structure configured in this way, when soil accumulates on the bottom surface of the first culture unit 13, the soil height measurement means 50 detects this and automatically operates the discharge means 70, so that the first culture unit (13) The soil accumulated on the bottom surface of 13) is discharged to the second aquaculture unit (15).

Therefore, the first aquaculture unit 13 prevents silt from accumulating on the bottom, and the second aquaculture unit 15 maintains a state where silt accumulates on the bottom, so that fish living in an environment without silt on the bottom can Fish that are cultured in the aquaculture unit 13 and live in an environment where soil is piled up on the bottom are cultured in the second aquaculture unit 15, which has the advantage of providing a variety of environments suitable for fish to live in.

10. Fish farm main body 20. Water supply channel
30. Drain 40. Waterproof fence

Claims (6)

A fish farm main body (10) formed concave downward on the ground so as to be close to the river (1) and having a water supply port (11) and a drain port (12) on the up and downstream sides,
A water supply path (20) branched from the river (1) and connected to the water supply port (11) of the fish farm main body (10),
It includes a drain 30 connecting the drain 12 of the fish farm main body 10 and the river 1,
A plurality of dams 17 are provided in the middle part of the fish farm main body 10,
The internal space of the fish farm main body (10) is
The first aquaculture unit 13 upstream,
A first submerged section (14) located downstream of the first aquaculture section (13),
A second aquaculture unit (15) located downstream of the first submerged unit (14),
It is divided into a second submerged section 16 located downstream of the second aquaculture section 15,
A fish farm structure characterized in that a passage (17a) for water and fish to pass through is formed in the dam (17).
According to clause 1,
Water plants are planted inside the first and second submerged parts (14, 16), and suspended matter contained in the water passing through the first and second submerged parts (14, 16) is filtered by the water plants. Fish farm structure.
According to clause 1,
The drain 12 of the fish farm main body 10 is constructed by combining drain pipes 11c and 11d so as to penetrate the dam 17 installed to block the entrance portion of the drain 30 in the up and down direction,
A fish farm structure, characterized in that a net (11b) is coupled to the ends of the drain pipes (11c, 11d).
According to clause 1,
A fish farm structure, characterized in that the water supply channel (20) is provided with a water supply gate (21) that controls the flow rate of water flowing in through the water supply channel (20).
According to clause 1,
It further includes a waterproof fence (40) provided around the circumference of the fish farm main body (10),
The waterproof fence (40) is
A support bar (41) provided on the circumference of the fish farm main body (10),
A fish farm structure, characterized in that it includes a waterproof cloth (42) fixed to the support (41) and the lower end of which is fixed to the upper surface of the circumference of the fish farm main body (10).
According to clause 1,
A plurality of soil height measurement means (50) provided inside the first culture unit (13) to measure the height of the soil accumulated on the bottom surface of the first culture unit (13),
It is installed to penetrate the embankment 17 so as to extend from the first culture unit 13 to the inside of the second culture unit 15, and the soil accumulated on the bottom surface of the first culture unit 13 is placed in the second culture unit. A plurality of discharge means (70) discharging to (15),
It further includes a control means (80) that receives a signal from the labor and management height measuring means and controls the operation of the discharge means (70),
The soil height measuring means (50) is
A lifting guide 51 provided to extend upward on the bottom surface of the first form part 13,
A lifting platform (52) coupled to the lifting guide (51) so as to be capable of being lifted up and down,
A cylinder mechanism (53) connected to the elevating platform (52) to raise and lower the elevating platform (52),
A close contact plate 54 coupled to the lower side of the elevating platform 52 to enable elevation,
Elevation detection means 55 provided on the elevating platform 52 and detecting when the gap between the elevating platform 52 and the contact plate 54 narrows,
Including height sensing means 56 for measuring the raised height of the lifting platform 52,
As the elevating platform 52 is lowered and the contact plate 54 touches the upper surface of the soil accumulated on the bottom surface of the first form part 13 and the rise detection means 55 detects this, the height detection means ( It is configured to measure the height of the soil by measuring the height of the platform 52 using 56),
The discharge means 70 is
A discharge pipe 71 installed to penetrate the dike 17 and extend from the first aquaculture unit 13 to the inside of the second aquaculture unit 15,
It includes a control valve 72 provided in the middle of the discharge pipe 71,
The upstream end of the discharge pipe 71 is arranged to be close to each other's soil height measurement means 50,
The control means 80 receives a signal from the soil height measuring means 50 and measures the corresponding soil height when any soil height measuring means detects that soil has accumulated on the bottom surface of the first form part 13. The control valve 72 provided in the discharge means 70 extended to approach the means 50 is opened to allow soil and water inside the first culture unit 13 to flow into the second culture unit through the discharge pipe 71. A fish farm structure characterized in that it is discharged into the interior of (15).

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