KR101324823B1 - Transporting box for live fish and shellfish - Google Patents

Abstract

PURPOSE: A transporting box for live fishes and shellfishes is provided to transport the live fishes and the shellfishes for a long time in a fresh state. CONSTITUTION: A transporting box (1) for live fishes and shellfishes comprises a body (10), an air supply port (20), and a cap. The body comprises a box unit for receiving the live fishes and the shell fishes with water; and a cover member (12) for sealing the box unit. The air supply port is arranged on the top of the body to inject oxygen into the sealed body. The cap seals a tube (41) and an insertion hole through which the internal water of the body is discharged to the outside by injected oxygen pressure when the oxygen in the body is lack. [Reference numerals] (AA) Oxygen

Description

Transporting box for live fish and shellfish}

The present invention relates to a live fish and shellfish shipping box, and more specifically, a live fish and shellfish transport box, such as fish or shellfish, with water, which is optimized for transporting a small amount alive, and at the same time, a small and small fish and shellfish transport box that can meet the optimum amount of oxygen. It is about.

In general, the best way to transport fish and shellfish such as fish and shellfish to their destination is to transport these fish alive. In order to transport fish and shellfish alive, that is, to transport live fish and shellfish, conventionally, a live transport vehicle Was used, and some used a transport box 101 as shown in FIG.

However, the live fish transport vehicle as described above has excessive logistic costs, has a limited loading amount, and there is a problem that the labor cost is not economical because a lot of labor costs are required to mount or unload live fish and shellfish on the vehicle.

In addition, the conventional live fish and shellfish transport box 101 is a box (air, oxygen generator 103 and the battery 105 for driving the same to generate air or oxygen in the box 101, as shown in FIG. 101) to be installed in the bar, so that the space for holding live fish shells therein, the weight is increased, the overall manufacturing unit price is increased, in particular, the oxygen generator 103 inside the sealed box 101 of limited quantity Oxygen generated by mixing with the secretions of live fish and shells to generate bubbles, which has a number of problems in terms of cost and handling, such as obstruction in raising the fresh fish shells.

The present invention has been proposed to solve the above problems, in accommodating a relatively small amount of live fish and shellfish with water, injecting the oxygen of the optimum amount to fill the inside of the body to seal the shellfish while raising the freshness of the live fish shellfish The aim is to reduce the costs associated with the transport of fish and shellfish, and to improve work efficiency.

In order to achieve this object, the present invention provides a container means for accommodating live fish and shellfish with water, and closing means for sealing and closing the container means after the live fish and shellfish and water are put into the container means. Consisting of a body; An air supply port opened in an upper side of the body to inject oxygen into the space in the body closed by the closing means; And it provides a live fish and shellfish transportation box consisting of a tube which is fixed to the insertion hole formed in the upper surface of the closing means.

In addition, the tube is preferably formed with a scale or a leader.

In addition, the air supply may further include a one-way valve mounted to the air supply to allow oxygen to be injected from the outside to the inside, but to prohibit the discharge of oxygen from the inside of the body.

In addition, the body preferably further comprises a buoy for reducing the rumble of the water contained therein during transportation.

In addition, the body preferably further comprises a coolant accommodating means for containing the coolant on the outer peripheral surface of the container means and / or the closing means.

In addition, it is preferable that the outer surface of the body and the coolant accommodating means are insulated by a heat insulating material.

In addition, the body is preferably made of a material at least a portion of which is not opaque.

In addition, the inner circumferential surface of the body is preferably marked with a metering line so as to measure the water level contained in the body.

In addition, the body preferably further includes a mantle disposed adjacent to the inner surface and covering the bottom surface to rise to the water surface of the water contained therein.

Therefore, according to the live fish and shellfish transportation box of the present invention, the live fish and shellfish with water in the body, and then sealed, and then transported after supplying the correct amount of oxygen, packaging live fish and shellfish to the individual through courier, etc. It can be transported to its destination for a long time for the retailing of fish, thus creating new opportunities in the logistics of live fish and shellfish.

In addition, the high pressure oxygen contained therein greatly increases the freshness of the live fish and shellfish, and is convenient to load in a vehicle, thereby significantly reducing the logistics work such as loading and unloading the live fish and shellfish on the vehicle and the resulting cost. .

In addition, since it can maintain the freshness of live fish and shellfish by itself, it is possible to utilize a general or cooling tower truck as a transport vehicle instead of live fish.

1 is a perspective view showing a conventional live fish and shellfish transportation box.
Figure 2 is a perspective view of a live fish shells shipping box according to the present invention.
3 is a sectional view of FIG. 2;
4 is a sectional view partially showing the opposite side to FIG. 3;
Fig. 5 is a sectional view showing another embodiment of the present invention.
Figure 6 is a sectional view showing another embodiment of the present invention.
Figure 7 is a cross-sectional view showing a state in which the oxygen injection of the live fish shellfish transport box according to the present invention is completed.
Figure 8 is a cross-sectional view of the capped state after the oxygen injection of the live fish shellfish transport box according to the present invention.

Hereinafter, a live fish shells shipping box according to a preferred embodiment of the present invention will be described in detail according to the accompanying drawings.

A transport box 1 according to a first embodiment of the invention is shown in FIGS. 2 to 4. As shown in these figures, the transport box 1 is generally composed of a body 10, an air supply 20, and a tube 41. Preferably, the tube is provided with a scale or a leader at regular intervals. If no scale or the like is formed, the same effect can be obtained by varying the diameter of the tube or the like. Hereinafter, the scale tube 41 will be described by way of example in order to help understanding of the present invention.

First of all, the body 10 forms the outer body of the transport box 1 as shown, and the container means 11, which is adapted to receive the live fish and shellfish S together with the water W, and the container means ( 11) After the water (W) and live fish shellfish (S) is made of a closing means 12 for sealing the container means (11).

Here, the container means 11, as shown in Figs. 2 and 3, handling the contents water soluble capacity that can efficiently contain the water (W) and live fish and shellfish (F) and can efficiently load or transport It is preferable to be manufactured in the form of a wide rectangular tube in consideration of the performance, etc., the closing means 12 is also a lid for sealing the container means 11, as with the container means 11, in consideration of the water-soluble capacity or handling performance container means It is preferable that it is manufactured in the shape of a wide square cylinder corresponding to (11).

However, the container means 11 may be made in any form as long as it can hold water (W) and fish and shellfish (F), and, of course, the finishing means 12 for closing the container means 11 is also a container means ( 11) After the water (W) and the shellfish (F) in the container means (11) can be closed if it can be produced in any form.

Insertion hole 40 is formed on the upper surface of the finishing means 12 so that the graduation tube 41 is engraved at regular intervals can be inserted, the graduation tube 41 is free to move up and down through the insertion hole The inner diameter of the insertion hole to match the diameter of the graduation tube so as not to be able to, or to install a separate stopper 42 in the insertion hole 40 to be fixed to the graduation tube 41. Preferably, the graduated tube 41 has a tubular shape in which the upper end and the lower end are open, and has a tube structure having a hollow part.

In addition, the body 10, as shown in Figure 5, the finishing means, i.e., the lid 12 is connected to the center of the inner surface through the string 22 or not shown, but without the strap buoy 13 floats on the water surface It can be, therefore, it is possible to reduce the rocking of the water (W) accommodated therein when transported by the buoy 13.

In addition, the body 10 may form a coolant accommodating means 18 on the outer wall, as shown in Figs. 5 and 6 to maintain the temperature inside the low temperature, this coolant accommodating means 18 also the body If the outer wall of the form (10) can be produced in a variety of forms in any of the bar, either the container means 11 or the finishing means 12 or only the container means 11 and both of the finishing means 12 It may be formed in, it is preferable to be manufactured in the form of a plate that is widely spread along the top or bottom of the container means 11 and the finishing means 12. The coolant accommodating means 18 naturally receives coolant C such as ice or a cooling pack as a means for cooling therein.

Furthermore, as shown in FIG. 6, the coolant accommodating means 18 may be thermally treated by attaching or applying the heat insulator 14 to the outer surface in order to more effectively maintain the cold air inside the body 10. The outer surface of the body 10 may be directly attached or applied by applying.

The body 10 is also preferably made of a rigid material that can be stacked in multiple stages, particularly in order to check the state of the live fish or shellfish F or the water level of the water W contained therein. It may be made of a material such as translucent acrylic, and the coolant accommodating means 18 may also be made of a part or the whole is not opaque to look at the state of the coolant (C) accommodated therein.

As such, when the body 10 is not at least partially opaque to check the water level contained in the water (W) contained therein, the visibility on the inner circumferential surface is secured as shown in FIG. 5 to more accurately check the water level. It is preferable to display the measurement line 15 at the site.

Finally, the body 10, as shown in Figure 6 so as to prevent the shellfish is attached to the inner circumferential surface, as well as the bottom surface of the container means 11 of the body 10, as well as the water (W) contained therein The mantle 16 is disposed adjacent to cover the inner side up to a height reaching the surface of the surface.

On the other hand, the air supply port 20 formed on one side of the upper surface of the body 10 is to inject oxygen into the remaining space (S) containing the water (W) inside the closing means 12, that is, the body 10 closed by a lid As a hole, it is preferable to penetrate the finishing means 12, that is, one side of the upper surface of the lid as shown in Figs.

In particular, the air inlet 20 is preferably provided with a one-way valve 21 at the distal end portion connected to the oxygen injection pipe (P), as shown in Figure 4, through the one-way valve 21, such as oxygen cylinder body 10 The oxygen is allowed to be injected into the body 10 from the outside, the oxygen injected into the body 10 can be prohibited to be discharged to the outside.

In addition, the graduation tube 41 is inserted into the upper surface of the finishing means 120 is fixed as the first function, the water (W) is pressed out due to the pressure of oxygen injected into the body 10 out of the body 10 It prevents the risk of leakage or breakage due to increased oxygen pressure.

That is, the graduation tube 41 is the water (W) when the pressure of oxygen introduced through the air inlet 20 into the sealed body 10 after the water (W) and live fish shellfish (F) is increased Can be exported out of the box (1).

Now, when explaining the operation of the live fish shellfish transport box (1) according to a preferred embodiment of the present invention configured as follows.

In order to transport live fish and shellfish by the live fish and shellfish transportation box 1 of the present invention, first, the container means 11 of the box 1, ie, the closing means 12 in the container, and then the water in the container means 11 (W) and live fish (F) are added in order.

At this time, as shown in FIGS. 5 and 6, if necessary, before the live fish shellfish (F), the nettle 16 may be disposed in the container means 11, the coolant receiving means 18 In this case, the coolant C may be introduced into the coolant accommodating means 18 to maintain the cold air.

Then, after closing the closing means 12 on the container means (11), and after sealing, the oxygen injection pipe (P) connected to the oxygen tank or the like connected to the one-way valve 21 of the air supply port 20, and then the sealed body ( 10) Injects oxygen into the interior, where the finishing means 12, buoy 13 and the drain pipe 30 may be disposed in place as shown in Figs.

Prior to injecting oxygen into the body space through the oxygen injection tube (P), the amount of oxygen required in the body is determined, and accordingly, the graduated tube 41 is inserted into the body to the depth where oxygen is to be filled. Insertion lock through 40. If the water surface inside the body is higher than the bottom of the graduated tube 41, that is, when the bottom of the graduated tube is submerged in water, the amount of oxygen is insufficient than the required level, on the contrary, when the water surface is lower than the bottom of the graduated tube If the bottom of the graduated tube floats on the surface of the water, the amount of oxygen is too high.

The graduated tube 41 has a scale formed at regular intervals so that the amount of oxygen inside the body can be set. For example, assuming that the scale is displayed in 10 equal parts with respect to the entire length, the amount of air is based on 10. If 8 is required, the upper part of the graduated tube is exposed by 2 and 8 is inserted inside.

Next, as shown in FIG. 7, oxygen is opened to inject oxygen until the body 10 is filled in the space through the oxygen injection pipe P, and the space S on the water surface is filled with oxygen. Even if oxygen is continuously injected into the body 10, the water W in the body 10 is discharged out of the box 1 through the graduation tube 41, which is the only outlet. There is no need to worry that 10) may rupture even minutely or leak oxygen.

As such, when the amount of oxygen is insufficient, the water inside the body is discharged through the graduated tube 41 by the pressure of the injected oxygen, and the water is discharged to the bottom of the graduated tube 41. At the time when the bottom of the graduated tube floats on the surface, oxygen is discharged to the outside through the hollow of the graduated tube 41 by the amount of oxygen injected thereafter, so that water is no longer discharged through the graduated tube 41. .

That is, when it is confirmed that air is discharged from the graduated tube 41 while continuously injecting oxygen through the one-way valve, it may be determined that oxygen of the required level is saturated in the internal space of the body. After that, the graduation tube 41 is removed, and the insertion hole 40 is closed by the cap 50 (Fig. 8).

In this way, if it is determined that the oxygen is filled in the body 10, the packaging of the live fish and shellfish by the live fish and shellfish transport box 1 of the present invention by closing the outlet of the insertion hole 40 with a cap, the packaged transportation The box 1 is loaded in multiple stages in a vehicle or the like and supplied to the consumer.

1: Transport Box 10: Body
11: container means 12: finishing means
13: buoy 14: insulation
15 metering line 16 mantle
18: coolant accommodating means 20: air supply
21: one-way valve 40: insertion hole
41: tube 42: stopper
50: cap
C: Coolant F: Live fish and shellfish
W: water

Claims (3)

A body consisting of a container means adapted to receive live fish and shellfish with water, and closing means for sealing and closing the container means after the live fish and shellfish and water are introduced into the container means; An air supply port provided on an upper side of the body to inject oxygen into the space in the body sealed by the closing means; And it is inserted into the insertion hole formed on the upper surface of the closing means is adjustable in height, and when the amount of oxygen in the body is insufficient, the tube for discharging the water inside the body to the outside with the pressure of the injected oxygen and the cap to seal the insertion hole Live seafood shells. The method of claim 1,
The tube is a live fish and shellfish transportation box, characterized in that the graduation or the indicator is formed. Inserting a tube into the insertion hole formed in the upper surface of the closing means of the live fish and shellfish transport box according to claim 1 or 2 and fixing the height;
Injecting oxygen into the air through the air supply to discharge water out of the body through the tube; And
If the water is not discharged through the tube is discharged air is judged that the water level control is completed, removing the tube and closing the insertion hole with a cap oxygen supply method in a live fish shells shipping box.

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