KR102656699B1 - A Shellfish Seed Net Input Apparatus - Google Patents

Abstract

The present invention relates to a shellfish seed fishing net insertion device, which consists of a frame part constituting a body, a hopper part installed above the frame part to receive seeds, and a certain amount of seeds stored in the hopper part downwardly. A fishing net is formed with a seed receiving part that accommodates a seed, a seed guide part that is located below the seed receiving part and guides the seeds of the seed receiving part, and a cut part that is opened upward and is located below the seed guide part. It is characterized by comprising a fishing net fixing part fixed to correspond to the discharge port, and a first cylinder that raises and lowers the fishing net fixing part so that the cut part of the fishing net is coupled to the discharge port of the seed guide part.

Description

Shellfish seed net input device {A Shellfish Seed Net Input Apparatus}

The present invention relates to a shellfish seed fishing net insertion device, and more specifically, to a shellfish seed fishing net insertion device that simply and safely distributes and inserts shellfish seeds into a fishing net.

In general, shellfish refers to the types of molluscs with calcareous shells, including Monoplacophora, Polyplacophora, and Prosobranchia of Gastropoda. It includes parts of Opisthobranchia, most of Pulmonata, most of Scaphopoda and Bivalvia, and part of Cephalopoda.

Among these, bivalve molluscs belonging to the bivalve class have left and right shells. Protobranchia, such as walnut clams, which are used as a food source, Filibranchia, such as oysters, and plates such as lilies. This includes Lamellibranchia and Septibranchia, including the great dipper clam.

On the other hand, oysters, a representative species of the order Cyprus, are characterized by asymmetrical left and right shells. They live a floating life during the larval stage, feeding on plankton in the water, and grow into spat about 20 days after hatching, then grow into rocks. It lives attached to its back.

For reference, oysters have been used as food for a very long time in human history, but recently, as their amazing efficacy has been scientifically revealed, they have been in the spotlight around the world. Oysters, commonly called 'milk of the sea', are rich in glycogen, an energy source for the human body, and zinc, an active source of sex hormones. They are high in vitamins and minerals, and absorb calcium quickly, making them highly effective in preventing diseases such as diabetes and high blood pressure, as well as digestion. It is easy to absorb and has excellent taste and aroma, making it loved by people of all ages.

And in response to this, the farming of bivalve shellfish, including oysters, is attracting attention.

General shellfish farming involves the processes of seedling, shell breeding, and harvesting. At this time, seedling is the process of obtaining seedlings, spat cultivation is the process of growing spat with a limited life range through artificial management, and harvesting is the collection of adult and spat.

However, the prior art had the following problems.

In the process of spat breeding, seeds are inserted into fishing nets and dropped into the sea, etc., but there was a problem in that inserting a certain amount of seeds into the space of a regularly divided fishing net was done manually, making the work cumbersome.

Registered Patent No. 10-2235851

In order to solve the above-mentioned problems, the purpose of the present invention is to provide a shellfish seed fishing net insertion device that easily and automatically inserts seeds into the fishing net.

In order to achieve the above-described object, the present inventor's shellfish seed fishing net insertion device includes a frame part constituting the body, a hopper part installed above the frame part to receive seeds, and a lower part for sending seeds contained in the hopper part. A seed receiving part that accommodates a certain amount of seed, a seed guide part located below the seed receiving part to guide the seeds of the seed receiving part, and a fishing net positioned below the seed guide part and forming a cut open at the top to form the seed. It is characterized by comprising a fishing net fixing part that is fixed to correspond to the discharge port of the guide part, and a first cylinder that raises and lowers the fishing net fixing part so that the cut part of the fishing net is coupled to the discharge port of the seed guide part.

The seed receiving unit includes a first rotation axis whose axis is formed horizontally, a cylindrical body rotating along the first rotation axis, and a receiving groove in which a groove recessed in the direction of the first rotation axis is formed on a side of the cylindrical body. It is characterized in that the upper surface of the receiving groove is formed in a polygon, and the vertex is located in front of the rotation direction of the cylindrical body portion.

The receiving groove includes a hole formed by a polygonal column, a polygonal bottom plate that rises and falls along the hole and forms the bottom of the polygonal column hole, and a second cylinder that provides power to move the polygonal bottom plate up and down. It is characterized by:

The seed guide part is formed in a funnel shape with an inner diameter that narrows downward, and includes a guide body part with an inlet at the top and a discharge port at the bottom, and guide protrusions extending downward on both sides of the outlet at the bottom of the guide body part. And, the side surfaces of the guide body portion and the guide protrusion are characterized in that they are formed as curved surfaces.

In addition, the shellfish seed fishing net feeding device of the present invention includes a rail formed on the bottom of the body, a sliding plate that moves along the rail and has a first cylinder formed above, and a second device that provides power to move the sliding plate. It is characterized in that it further includes a cylinder.

The shellfish seed fishing net insertion device according to the present invention has the following effects.

As the fishing net fixing part that fixes the fishing net moves up and down to the bottom of the seed guide part that guides the seeds, approaching or moving away, the seed guide part is safely inserted into the cut part of the fishing net, and the seeds of the seed receiving part are safely inserted into the space of the fishing net, making work easier. There is.

Figure 1 is a configuration diagram showing a preferred embodiment of the shellfish seed fishing net input device according to the present invention.
Figures 2a and 2b are views showing the input port of the seed receiving part constituting the shellfish seed fishing net input device of the present invention.
Figure 3 is a view showing the configuration of the receiving groove of the seed receiving part constituting the shellfish seed fishing net input device of the present invention.
Figure 4 is a diagram showing the configuration of the seed guide part constituting the shellfish seed fishing net input device of the present invention.
Figure 5 is a configuration diagram showing another preferred embodiment of the shellfish seed fishing net input device according to the present invention.
Figure 6 is a front view showing a preferred embodiment of the shellfish seed fishing net input device according to the present invention.
Figure 7 is a diagram showing the configuration of the seed receiving part constituting the shellfish seed fishing net input device according to the present invention.
Figure 8 is a view showing another embodiment of the receiving groove of the seed receiving part constituting the shellfish seed fishing net input device according to the present invention.

Hereinafter, a preferred embodiment of the shellfish seed fishing net input device according to the present invention will be described in detail with reference to the attached drawings.

First, as shown in FIG. 1, the shellfish seed fishing net input device of the present invention includes a frame part 1 constituting the body, and a hopper part 10 installed above the frame part 1 to receive seeds. and a seed receiving unit 20 that receives a certain amount of seeds accommodated in the hopper unit 10 downward, and a seed located below the seed receiving unit 20 to guide the seeds of the seed receiving unit 20. A guide portion 30 and a fishing net 50 located below the seed guide portion 30 and formed with a cut portion 52 opening upward are selectively fastened to the discharge port of the seed guide portion 30. A fishing net fixing part 40 and a first cylinder 42 that raises and lowers the fishing net fixing part 40 so that the cut part 52 of the fishing net 50 is coupled to the discharge port of the seed guide part 30. It can be done including.

First, the shellfish seed fishing net input device of the present invention is provided with a frame portion (1). The frame portion 10 constitutes the skeleton of the shellfish seed fishing net insertion device of the present invention.

A hopper part 10 is provided in the frame part 1. As shown in FIG. 1, the hopper unit 10 is provided above the frame unit 10 and serves to receive and store seeds supplied from the outside. Only the bottom of the hopper part 10 can be formed of a transparent material.

The hopper unit 10 may be made of a transparent material. This is to check the condition of the seeds loaded inside the hopper unit 10 and whether the seeds are safely guided to the seed receiving unit 20, which will be described below.

A transparent window 12 may be further provided in the hopper unit 10. As shown in FIG. 6, the transparent window 12 is provided at the bottom of the front of the hopper unit 10 so that it can be confirmed whether there are seeds inside the hopper unit 10.

The top of the hopper unit 10 may be formed to be inclined. This is to easily insert the seeds into the hopper unit 10.

A seed receiving part 20 is provided below the hopper part 10. The seed receiving part 20 serves to receive a certain amount of seeds loaded in the hopper part 10 through the lower part of the hopper part 10. And, the seed receiving part 20 serves to deliver the certain amount of seeds to the seed guide part 30, which will be described below.

The seed receiving part 20 may be configured in various ways for the above-described functions, and in the present invention, may be configured as follows.

As shown in FIG. 1, the seed receiving portion 20 includes a first rotation axis 22 whose axis is formed horizontally, a cylindrical body portion 24 rotating along the first rotation axis 22, and The cylindrical body portion 24 may include a receiving groove 26 in which a groove is formed on a side surface of the cylindrical body 24 in the direction of the first rotation axis 22.

As shown in FIGS. 1 and 2, the seed receiving part 20 is provided with a first rotation axis 22 whose axis is formed horizontally. In addition, a cylindrical body portion 24 that rotates along the first rotation axis 22 is provided. A receiving groove 26, which is a recessed groove, is formed on the side of the cylindrical body portion 24.

A motor (not shown) is provided in the cylindrical body portion 24. The motor serves to provide power so that the cylindrical body portion 24 rotates along the first rotation axis 22. As the motor operates and the cylindrical body 24 rotates about the first rotation axis 22, the top of the receiving groove 26 formed on the side of the cylindrical body 24 is positioned vertically or forward. Make it possible.

In addition, the receiving groove 26 distributes a certain amount of seeds from the hopper unit 10 and feeds them into the partitioned fishing net 50, and can be configured to control the amount of seeds.

As shown in FIG. 3, the receiving groove 26 has a hole 27 formed as a polygonal pillar, and rises and falls along the hole 27 to form the bottom of the hole 27 of the polygonal pillar. It may include a polygonal bottom plate 28 and a second cylinder 29 that provides power to move the polygonal bottom plate 28 up and down.

A hole 27 is formed in the receiving groove 26. The hole 27 is formed in the shape of a polygonal column. In particular, the entrance of the hole 27 is formed in a polygon, as shown in FIG. 2, and the vertex can be located in the direction of travel.

This causes friction with the lower end of the hopper part 10 as the seed receiving part 20 rotates, and is located on the surface of the receiving groove 26 of the hopper part 10 and the seed receiving part 20. This is to prevent the seeds from being damaged.

The entrance of the hole 27 may be configured in a rectangular shape, as shown in FIGS. 2A and 2B. That is, the entrance of the hole 27 may be formed to have a relatively small width relative to the length in the traveling direction. For example, as shown in FIGS. 2A and 2B, it may be formed in a rectangular pentagon or diamond shape.

The entrance of the hole 27 may be configured as shown in FIG. 7 when considering the overall configuration of the cylindrical body portion 24.

The receiving groove 26 is designed to control the amount of seeds loaded inside the receiving groove 26 by adjusting the height of the bottom surface of the receiving groove 26 formed in the seed receiving portion 20. That is, due to the operation of the second cylinder 29, the polygonal bottom plate 28 moves up and down the hole 27 and adjusts the size of the space inside the hole 27.

Of course, the polygonal bottom plate 28 may be manually fixed by an operator using a clamp or the like that can be fixed to the inner wall of the receiving groove 26.

And, as shown in FIG. 8, another embodiment of the receiving groove 26 includes a hole 27 formed as a polygonal pillar, and the hole 27 of the polygonal pillar while rising and falling along the hole 27. ), the polygonal bottom plate 28 forming the bottom, the second cylinder 29 that provides power to move the polygonal bottom plate 28 up and down, and the receiving groove 26 are shown in Figure 3. As described above, a hole 27 formed of a polygonal pillar, a polygonal floor plate 28 that rises and falls along the hole 27 and forms the bottom of the hole 27 of the polygonal pillar, and the polygonal floor plate (28) may include a second cylinder (29) that provides power to move up and down, and a buffer portion (25) that provides elastic support between the polygonal bottom plate (28) and the second cylinder (29). there is.

A hole 27 is formed in the receiving groove 26. The hole 27 is formed in the shape of a polygonal column. In particular, the entrance of the hole 27 is formed in a polygon, as shown in FIG. 2, and the vertex can be located in the direction of travel.

This causes friction with the lower end of the hopper part 10 as the seed receiving part 20 rotates, and is located on the surface of the receiving groove 26 of the hopper part 10 and the seed receiving part 20. This is to prevent the seeds from being damaged.

The entrance of the hole 27 may be configured in a rectangular shape, as shown in FIGS. 2A and 2B. That is, the entrance of the hole 27 may be formed to have a relatively small width relative to the length in the traveling direction. For example, as shown in FIGS. 2A and 2B, it may be formed in a rectangular pentagon or diamond shape.

The receiving groove 26 is designed to control the amount of seeds loaded inside the receiving groove 26 by adjusting the height of the bottom surface of the receiving groove 26 formed in the seed receiving portion 20. That is, due to the operation of the second cylinder 29, the polygonal bottom plate 28 moves up and down the hole 27 and adjusts the size of the space inside the hole 27.

Of course, the polygonal bottom plate 28 may be manually fixed by an operator using a clamp or the like that can be fixed to the inner wall of the receiving groove 26.

A hole 27 is formed in the receiving groove 26. The hole 27 is formed in the shape of a polygonal column. In particular, the entrance of the hole 27 is formed in a polygon, as shown in FIG. 2, and the vertex can be located in the direction of travel.

This causes friction with the lower end of the hopper part 10 as the seed receiving part 20 rotates, and is located on the surface of the receiving groove 26 of the hopper part 10 and the seed receiving part 20. This is to prevent the seeds from being damaged.

The entrance of the hole 27 may be configured in a rectangular shape, as shown in FIGS. 2A and 2B. That is, the entrance of the hole 27 may be formed to have a relatively small width relative to the length in the traveling direction. For example, as shown in FIGS. 2A and 2B, it may be formed in a rectangular pentagon or diamond shape.

The receiving groove 26 is designed to control the amount of seeds loaded inside the receiving groove 26 by adjusting the height of the bottom surface of the receiving groove 26 formed in the seed receiving portion 20. That is, due to the operation of the second cylinder 29, the polygonal bottom plate 28 moves up and down the hole 27 and adjusts the size of the space inside the hole 27.

Of course, the polygonal bottom plate 28 may be manually fixed by an operator using a clamp or the like that can be fixed to the inner wall of the receiving groove 26.

Additionally, a buffer portion 25 may be further provided between the polygonal bottom plate 28 and the second cylinder 29. When seeds are loaded on the upper surface of the polygonal bottom plate 28, the buffer portion 25 absorbs the impact applied to the polygonal bottom plate 28 and prevents the seeds from being damaged. It plays a role.

As shown in FIG. 3, the receiving groove 26 has a hole 27 formed as a polygonal pillar, and rises and falls along the hole 27 to form the bottom of the hole 27 of the polygonal pillar. It may include a polygonal bottom plate 28 and a second cylinder 29 that provides power to move the polygonal bottom plate 28 up and down.

A hole 27 is formed in the receiving groove 26. The hole 27 is formed in the shape of a polygonal column. In particular, the entrance of the hole 27 is formed in a polygon, as shown in FIG. 2, and the vertex can be located in the direction of travel.

This causes friction with the lower end of the hopper part 10 as the seed receiving part 20 rotates, and is located on the surface of the receiving groove 26 of the hopper part 10 and the seed receiving part 20. This is to prevent the seeds from being damaged.

The entrance of the hole 27 may be configured in a rectangular shape, as shown in FIGS. 2A and 2B. That is, the entrance of the hole 27 may be formed to have a relatively small width relative to the length in the traveling direction. For example, as shown in FIGS. 2A and 2B, it may be formed in a rectangular pentagon or diamond shape.

The receiving groove 26 is designed to control the amount of seeds loaded inside the receiving groove 26 by adjusting the height of the bottom surface of the receiving groove 26 formed in the seed receiving portion 20. That is, due to the operation of the second cylinder 29, the polygonal bottom plate 28 moves up and down the hole 27 and adjusts the size of the space inside the hole 27.

Of course, the polygonal bottom plate 28 may be manually fixed by an operator using a clamp or the like that can be fixed to the inner wall of the receiving groove 26.

In addition, a seed guide part 30 is provided below the seed receiving part 20. The seed guide portion 30 is located below the seed receiving portion 20 and serves to guide the seeds of the seed receiving portion 20 into the fishing net 50, which will be described below.

The seed guide unit 30 can be configured in various ways for the above-described functions, and in the present invention, it can be configured as follows.

As shown in FIG. 4, the seed guide portion 30 is formed in a funnel shape with an inner diameter that narrows downward, and the guide body portion 32 is formed with an inlet 32a at the top and a discharge port 32b at the bottom. ) and guide protrusions 34 extending downward on both sides of the lower discharge port 32b of the guide body 32, and the side surfaces of the guide body 32 and the guide protrusions 34 are It can be formed into a curved surface.

The seed guide portion 30 is provided with a guide body portion 32. The guide body portion 32 is formed in a funnel shape to form an internal space penetrating upward and downward, and the inner diameter is formed to become narrower as it goes downward. When the seed is input into the receiving groove 26 of the seed receiving part 20 through the upper inlet 32a of the guide body part 32, it moves along the guide body part 32 and opens the discharge port 32b. It is put into the fishing net (50) through it.

A guide protrusion 34 is provided below the guide body portion 32. The guide protrusion 34 protrudes to extend downward on both sides of the lower discharge port 34b of the guide body portion 32. This allows the fishing net 50 described below to enter the seed guide portion 30. This is to ensure that the cutout portion 52 of the fishing net is safely opened by the guide protrusion 34 of the guide body portion 32 and the lower end of the seed guide portion 30 is inserted.

Side surfaces of the guide body portion 32 and the guide protrusion 34 are formed as curved surfaces. Of course, it is formed by the lower end of the guide protrusion 34 and a curved surface. This is to ensure that the guide protrusion 34 is safely guided when guided to the cut portion 52 of the fishing net 50.

In addition, a fishing net fixing part 40 is provided below the seed guide part 30. The fishing net fixing part 40 is located below the seed guide part 30, and the fishing net 50, which has a cut part 52 opening upward, is formed at the discharge port 34b of the seed guide part 30. It plays a role in fixing it to match.

The fishing net fixing part 40 can be configured in various ways for the above-described function, for example, by pulling and fixing both ends of the fishing net 50 so that the opening 52 of the fishing net 50 is opened by the seed guide part ( It is located at the discharge port (32b) of 30). In particular, when several partitioned spaces are formed inside the fishing net 50 and several guide body parts 32 of the seed guide part 30 corresponding to each are formed, the fishing net ( 50) plays a role in safely fixing it.

In addition, a first cylinder 42 is provided below the fishing net fixing part 40. The first cylinder 42 serves to provide power to raise and lower the fishing net fixing part 40.

The first cylinder 42 operates to raise the fishing net fixing part 40 so that the discharge port 32b and the guide protrusion 34 of the seed guide part 30 are inserted into the cut part 52 of the fishing net 50. is inserted, and the first cylinder 42 operates to lower the fishing net fixing part 40 so that the discharge port 32b of the seed guide part 30 is located in the cut part 52 of the fishing net 50. Make sure it is removed.

The fishing net fixing unit 40 can be raised and lowered manually, and any means that can raise and lower the fishing net fixing unit 40 can be applied.

And, a rail 2 is provided on the bottom surface of the frame portion 1. The rail 2 is positioned so that the sliding plate 3, which will be described below, moves forward and backward of the frame portion 1.

A sliding plate (3) is provided above the rail (2). The fishing net fixing part 40 and a first cylinder 42 for raising and lowering the fishing net fixing part 40 are fixed to the sliding plate 3 upward. A third cylinder (4) is provided on one side of the sliding plate (3). The third cylinder (4) operates to move the sliding plate (3) to be positioned inside the frame portion (1) or discharged to the outside of the frame portion (1).

In addition, a control unit (not shown) that selectively drives the first cylinder 42, the third cylinder 4, the second cylinder 29, and the motor is further provided.

Next, the operation of the shellfish seed fishing net insertion device according to the present invention will be described in detail.

First, seeds are put into the hopper unit (10). Then, the fishing net 50 is fixed to the fishing net fixing part 40, and the cut part 52 of the fishing net 50 is positioned upward.

Then, when the control unit is driven, the control unit causes the second cylinder 4 to operate so that the fishing net fixing unit 40 is positioned below the seed guide unit 30. When the fishing net fixing part 40 is located below the seed guide part 30, the position sensor recognizes it, and when the control unit receives the signal, the control unit transmits a driving signal to the first cylinder 42.

The first cylinder 42 operates to raise the fishing net fixing part 40, so that the discharge port 32a and the guide protrusion 34 of the seed guide part 30 are aligned with the cut portion 52 of the fishing net 50. ) to be inserted.

Then, the motor is driven, so that the seeds loaded in the receiving groove 26 of the seed receiving part 20 are rotated and transferred to the seed guide part 30, and the seeds are It descends along the seed guide part 30 and is inserted into the fishing net 50.

As such, a person skilled in the art will understand that the technical configuration of the present invention described above can be implemented in other specific forms without changing the technical idea or essential features of the present invention.

Therefore, the embodiments described above should be understood in all respects as illustrative and not static, and the scope of the present invention is indicated by the claims described later rather than the detailed description above, and the meaning and scope of the claims and their Any changes or modifications derived from the equivalent concept should be construed as being included in the present invention.

1: Frame part 2: Rail
3: sliding plate 4: third cylinder
10: Hopper part 20: Seed receiving part
22: first rotation axis 24: cylindrical body portion
26: Accommodation groove 27: Home
28: polygonal bottom plate 29: second cylinder
30: Seed guide part 32: Guide body part
32a: Inlet 32b: Discharge port
34: Guide projection 40: Fishing net fixing part
50: fishing net 52: incision

Claims (5)

Frame portion constituting the body;
A hopper unit installed above the frame unit to accommodate seeds;
A seed receiving portion that receives a certain amount of seeds accommodated in the hopper portion downward;
A seed guide portion located below the seed receiving portion and guiding the seeds of the seed receiving portion;
A fishing net fixing part that is located below the seed guide part and fixes the fishing net in which a cut part opening at the top is formed so as to correspond to the discharge port of the seed guide part; and
It includes a first cylinder that raises and lowers the fishing net fixing portion so that the cut portion of the fishing net is coupled to the discharge port of the seed guide portion,
The seed receiving part,
A first rotation axis formed horizontally;
a cylindrical body rotating along the first rotation axis; and
It includes a receiving groove in which a groove recessed in the direction of the first rotation axis is formed on a side of the cylindrical body portion,
A shellfish seed fishing net input device, characterized in that the upper surface of the receiving groove is formed in a polygon, and the vertex is located in front of the rotation direction of the cylindrical body portion. delete According to clause 1,
The receiving groove is,
A hall formed by polygonal pillars;
a polygonal floor plate that rises and descends along the hole and forms the bottom of the polygonal column hole; and
a second cylinder that provides power to move the polygonal floor plate up and down;
A shellfish seed fishing net input device comprising a. According to clause 1,
The seed guide part,
A guide body portion formed in a funnel shape with an inner diameter that narrows as it goes downward, with an inlet at the top and an outlet at the bottom;
It includes guide protrusions extending downward on both sides of the discharge port below the guide body,
A shellfish seed fishing net input device, characterized in that the guide body portion and the side surfaces of the guide protrusion are formed as curved surfaces. According to clause 1,
A rail formed on the bottom surface of the frame unit;
A sliding plate that moves along the rail and has a first cylinder formed above it; and
a second cylinder that provides power to move the sliding plate;
A shellfish seed fishing net input device further comprising: