KR102294636B1 - Fish Hold Module for Small Vessel - Google Patents

Abstract

The present invention relates to a fishing rod module for a small vessel for transporting live fish in a alive state, comprising: a fishing rod installed in the hull 100 of a ship and providing a space for accommodating seawater and live fish; an external seawater supply line 320 for supplying seawater outside the hull 100 to the fishing rod 200; an external seawater supply pump 310 installed on the external seawater supply line 320, actively drawing in seawater from the outside of the hull 100 and supplying it into the fishing rod 200; and a seawater cooling device 400 that drains some of the seawater in the fishing rod 200, cools it, and then supplies it to the fishing rod 200 again.

Description

Fish Hold Module for Small Vessel}

The present invention relates to a fishing rod module for a small vessel, and more particularly, to a fishing vessel module for a small vessel capable of freely supplying seawater and effectively controlling the temperature in the fishing vessel.

A fishing rod 620 for transporting the captured fish to the land in a live fish state is installed in the small vessel 600 mainly used as a fishing boat (see FIG. 1 ). The seawater supplied from the outside of the hull is injected into the fishing hock installed in the conventional small vessel, and normally, if the seawater inlet is left open, seawater naturally flows in and fills the fishing hock 620 . In recent years, aluminum is widely used as a material for small ships, and aluminum ships have a shallow draft (see Fig. By this, it was difficult to fill a sufficient amount of seawater in the fishing rod 620 .

Furthermore, if there is a large amount of live fish in the fish tank, the seawater temperature in the fish tank rises. In this case, the survival rate of live fish may decrease, so maintaining the sea water temperature in the fish tank becomes an important issue. In the case of large fishing boats, a cooling device for cooling the temperature of the seawater in the fishing dock is used, but it was not easy to apply such a cooling device to a small fishing boat. In particular, when the cooled seawater flows into the fishing rod, a large temperature difference occurs between the portion to which the cooling water is supplied and the portion to which the cooling water is supplied (that is, a large temperature gradient occurs within the fishing rod), and the live fish is stressed can receive

Registered Patent Publication No. 10-0686730 (Registration Date: 2007.02.16.) Registered Utility Model Publication No. 20-0479009 (Registration Date: 2015.12.03.) Registered Utility Model Publication No. 20-0257998 (Registration Date: 2001.12.06.)

An object of the present invention is to solve the problems of the prior art described above, and at the same time to make it possible to easily supply seawater to a fishing rod installed in a small aluminum vessel, and to effectively control the temperature in the fishing vessel.

Furthermore, it is another object to minimize the non-uniformity of the temperature distribution of seawater in the fish tank, that is, the temperature gradient, caused by the cooled seawater supplied into the fish tank.

The present invention relates to a fishing rod module for a small vessel for transporting live fish in a alive state, comprising: a fishing rod installed inside the hull 100 of a vessel and providing a space for accommodating seawater and live fish; an external seawater supply line 320 for supplying seawater outside the hull 100 to the fishing rod 200; An external seawater supply pump 310 installed on the external seawater supply line 320, actively drawing in seawater from the outside of the hull 100 and supplying it into the fishing rod 200; And it characterized in that it comprises a seawater cooling device 400 that drains some of the seawater in the fishing rod 200, and then supplies it back to the fishing rod 200 after cooling it.

One end of the external seawater supply line 320 may be connected to the ballast tank 150 provided in the hull 100 , and the seawater stored in the ballast tank 150 may be supplied to the fishing rod 200 .

And it further includes a seawater mixing tank 800 that provides a space for storing seawater separately from the fishing rod 200, but one end of the seawater discharge line 510 in the fishing rod for discharging seawater from the fishing rod 200 is Connected to the fishing rod 200, the other end is branched into two, one of which is a seawater mixing tank inlet line 540 connected to the seawater mixing tank 800, and the other end is the seawater inlet of the seawater cooling device 400. Forms a cooling device inlet line 530 connected to, one end of the cooling device discharge line 550 is connected to the seawater outlet of the seawater cooling device 400, and the other end is connected to the seawater mixing tank 800, and , one end of the seawater supply line 520 in the fish tank is connected to the seawater mixing tank 800, and the other end is connected to the fish tank 200, so that the seawater cooled in the seawater cooling device 400 is the cooling device It is supplied into the seawater mixing tank 800 through the discharge line 550, and mixed with the seawater introduced through the seawater mixing tank inlet line 540 in the seawater mixing tank 800, and the seawater mixing tank ( The seawater in 800) is characterized in that it is supplied to the fishing rod 200 through the seawater supply line 520 in the fishing rod.

Finally, the amount of seawater flowing through the seawater discharge line 510 in the fishhook and the trench supply line 520 in the fishhook flows through the cooling device inlet line 530 and the cooling device discharge line 550 . It is characterized by more than the amount of seawater.

The fishing rod for a small aluminum vessel according to the present invention supplies seawater by using a pump, so that even a fishing rod installed in a small aluminum vessel can be filled with seawater to a predetermined height without great difficulty.

Furthermore, when the temperature of the seawater in the fishing rod is high due to the high density of live fish, the survival rate of live fish can be increased by cooling it and then forming a cycle of supplying it back into the fishing vessel, thereby controlling the seawater temperature in the fishing vessel. And when the cooled seawater is supplied into the fishing rod, by minimizing the temperature difference (temperature gradient) of the seawater between the region to which the cooled seawater is supplied and the remaining region, it is possible to minimize the stress that the live fish receives due to the temperature gradient.

1 shows the structure of a fishing rod in the hull according to the prior art.
Figure 2 shows the structure of a fishing rod in the hull according to the present invention.
3 and 4 discloses the concept of a fish tank module equipped with a seawater cooling device according to the present invention.
5 to 7 show various embodiments of a fishing rod module for a small vessel according to the present invention.

Hereinafter, the overall configuration of the fishing rod module for a small aluminum vessel according to the present invention will be described with reference to the drawings. Specific structural or functional descriptions presented in the embodiments of the present invention are only exemplified for the purpose of describing embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. In addition, it should not be construed as being limited to the embodiments described herein, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Figure 2 shows a cross-section of a small aluminum vessel. In general, when the hull 100 is manufactured from aluminum, it is impossible to introduce a sufficient amount of seawater into the fishing rod 200 only by natural inflow of seawater because of its large buoyancy compared to FRP ships or wooden ships. Therefore, as shown in FIG. 2 ( a ), when the external seawater supply pump 310 is installed in the external seawater supply line 320 to supply seawater from the outside of the hull 100 into the fishing rod 200 , the water surface in the fishing rod Since the height of 220 can rise higher than the sea level (WL), it is possible to supply a sufficient amount of sea level to the fishing rod 200 installed in the aluminum vessel.

Figure 2 (b) shows an embodiment in which the external seawater supply line 320 is connected to the ballast tank 150 formed in the hull 100 instead of directly leading to the outside of the hull 100. Since external seawater has already been introduced into the ballast tank 150 , it is supplied to the fishing rod 200 . Through this embodiment, the length of the external seawater supply line 320 can be reduced. In particular, in recent years, when seawater is introduced into the ballast tank 150, various types of seawater purification facilities (ultraviolet sterilization devices) for removing harmful microorganisms contained in seawater are often provided in the ballast tank, so the ballast tank 150 ) when the seawater is supplied to the fishing rod 200, naturally purified seawater is supplied to the fishing rod 200, thereby helping to maintain the freshness of the live fish.

3 is to maintain the seawater temperature in the fishing chang 200 at a certain level, by discharging some of the seawater in the fishing chang 200 (d1), and after cooling it by the seawater cooling device 400, the fishing chang 200 again It shows the concept of supplying (s1) into. Since the seawater cooling device 400 may use a conventional water cooling device, a detailed description thereof will be omitted.

At this time, in order to effectively control the temperature in the fishing window 200, the flow rate of the seawater to be cooled must be sufficient. Considering the size and cost of the seawater cooling device 400 that can be installed in a small fishing vessel, large-capacity seawater cooling Installing the device can actually be difficult. In this case, there is no choice but to install the seawater cooling device 400 with a small cooling capacity, but when it is necessary to significantly lower the seawater temperature in the fishing window 200 because the amount of supplied seawater is small, the output of the seawater cooling device 400 is increased Therefore, the temperature of the cooled seawater should be reduced as much as possible.

In this case, although the amount of the cooled seawater s1 supplied to the fishing rod 200 is small, since the temperature is significantly lower than that of the seawater filling the inside of the fishing rod 200, the region into which the cooled seawater flows has a large temperature. will be lowered That is, since the temperature gradient appears large around the area where the cooled seawater flows in the fishing rod 200 , the live fish swimming in the fishing rod 200 may be stressed and the survival rate may be lowered.

4 discloses a concept that can minimize the temperature gradient in the fishing window 200 even when a seawater cooling device with a small amount of water that can be cooled as described above is used. First, when the seawater temperature in the fishing rod 200 is out of the optimum temperature range, a portion of the seawater is discharged from the fishing rod 200 (d2), and the amount is set to be larger than the processing capacity of the seawater cooling device 400 . A portion of the seawater leaked from the fishing rod 200 is supplied to a separate water tank referred to as the seawater mixing tank 800 (d4), and a portion is supplied to the seawater cooling device 400 (d3).

The seawater cooled by the seawater cooling device 400 is supplied to the seawater mixing tank 800, and in the seawater mixing tank 800, the seawater that was supplied to the seawater mixing tank 800 among the seawater discharged from the fishing rod 200 ( d4) is mixed. Again, the seawater of the seawater mixing tank 800 is supplied to the fishing chang 200 (s2), at this time, the amount of cooled seawater supplied from the seawater mixing tank 800 to the fishing chang 200 is the amount of the seawater cooling device 400 . It is larger than the amount of cooling, and the temperature is slightly elevated.

That is, even if the seawater cooling device 400 with a slightly smaller processing capacity is used, the amount of seawater supplied into the fishing rod 200 is increased and the temperature difference is reduced, thereby reducing the temperature gradient in the fishing rod 200, which is a live fish By reducing the stress of live fish, the survival rate of live fish is increased.

Figure 5 shows an embodiment of a fishing rod module for a small aluminum vessel according to an embodiment of the present invention. The seawater discharge line 510 in the fishing rod that drains the seawater of the fishing rod 200 is branched to form a seawater mixing tank inlet line 540 leading to the seawater mixing tank 800 at one end, and the seawater cooling device 400 at the other end. ) to form a cooling device inlet line 530 leading to the inlet. The cooling device discharge line 550 from the outlet of the seawater cooling device 400 again leads to the seawater mixing tank 800, and again from the seawater mixing tank 800 to the fishing cage 200. goes on Here, since the amount of seawater flowing out and re-introduced in the fishing rod 200 is greater than the processing capacity of the seawater cooling device 400 , the seawater discharge line 510 and the seawater inlet line 520 in the fishing rod are cooling devices. It is preferable to be made larger than the inlet line 530 and the cooling device outlet line 550 . More preferably, in order to facilitate the flow of seawater, it is good to install the seawater discharge pump 420 or the cooling seawater supply pump 410 in the fishhook.

Figure 6 shows an embodiment of a fishing rod module for a small aluminum vessel according to another embodiment of the present invention. Unlike the embodiment of Figure 5, instead of reducing the size of the seawater supply line 520 in the fish tank, the number was increased. In this case, instead of increasing the area in which the cooled seawater is supplied into the fishhook 200 , the amount of cooled seawater supplied in one area decreases, which helps to reduce the temperature gradient in the fishhook 200 . And by installing the seawater mixing tank stirring means 430 in the seawater mixing tank 800, the seawater introduced through the seawater mixing tank inlet line 540 and the cooled seawater introduced through the cooling device discharge line 550 evenly can be mixed.

Figure 7 relates to a fishhook module for a small aluminum vessel according to another embodiment, which is a further improvement of the seawater supply line 520 in the fishhook disclosed in the embodiment of FIG. Since the seawater supply line 520 is branched into a plurality of pieces and is connected to multiple areas of the four sidewalls of the fishing window 200, the area to which the cooled seawater is supplied is larger, and the cooled seawater supplied from one area is expanded. Since the amount is reduced, it is possible to maximize the effect of reducing the temperature gradient in the fishing rod 200 .

100: hull 150: ballast tank
200: fish tank 220: sleep in fish tank
310: external seawater supply pump 320: external seawater supply line
400: seawater cooling device 410: cooling seawater supply pump in the fish tank
420: seawater discharge pump in the fish tank 430: agitating means for seawater mixing tank
510: seawater discharge line in fish tank 520: seawater supply line in fish tank
530: cooling device inlet line 540: seawater mixing tank inlet line
550: cooling device discharge line 800: seawater mixing tank
600: the hull of a conventional ship 620: a conventional fishing rod

Claims (4)

It relates to a fishing rod module for a small ship for transporting live fish in a alive state,
Doedoe installed inside the hull 100 of the ship, a fishing rod 200 that provides a space for accommodating seawater and live fish;
an external seawater supply line 320 for supplying seawater outside the hull 100 to the fishing rod 200;
An external seawater supply pump 310 installed on the external seawater supply line 320, actively drawing in seawater from the outside of the hull 100 and supplying it into the fishing rod 200;
a seawater cooling device 400 that drains some of the seawater in the fishing rod 200 and supplies it back to the fishing rod 200 after cooling it; and
Including a seawater mixing tank 800 that provides a space for storing seawater separately from the fishing rod 200,
One end of the seawater discharge line 510 in the fishing rod for discharging seawater from the fishing rod 200 is connected to the fishing rod 200, and the other end is branched into two seawater, one of which is connected to the seawater mixing tank 800. A mixing tank inlet line 540, the other one forms a cooling device inlet line 530 connected to the seawater inlet of the seawater cooling device 400,
One end of the cooling device discharge line 550 is connected to the seawater outlet of the seawater cooling device 400, and the other end is connected to the seawater mixing tank 800,
One end of the seawater supply line 520 in the fish tank is connected to the seawater mixing tank 800, and the other end is connected to the fish tank 200,
The seawater cooled by the seawater cooling device 400 is supplied into the seawater mixing tank 800 through the cooling device discharge line 550 , and the seawater mixing tank inlet line 540 in the seawater mixing tank 800 . ) and mixed with seawater introduced through
The seawater in the seawater mixing tank 800 is a fishing rod module for a small vessel, characterized in that it is supplied to the fishing rod 200 through the seawater supply line 520 in the fishing rod.
The method according to claim 1, wherein one end of the external seawater supply line 320 is connected to the ballast tank 150 provided in the hull 100, the seawater stored in the ballast tank 150 is supplied to the fishing rod 200 Characterized in that, a small vessel fishing rod module.
delete The method according to claim 1, The amount of seawater flowing through the seawater discharge line (510) in the fishhook and the trench supply line (520) in the fishhook, the cooling device inlet line (530) and the cooling device discharge line (550) Characterized in that more than the amount of seawater flowing through, small vessel fishing module.

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