JP2024077283A - Rearing device for prawn larvae - Google Patents

Abstract

[Problem] The objective of the present invention is to provide a breeding device for freshwater prawn larvae that reduces water temperature changes in the breeding tank, makes it difficult for temperature distribution in the water to occur in the breeding tank, and does not induce strong water currents in the breeding tank, thereby preventing the death of the freshwater prawn larvae and improving their survival rate. [Solution] The breeding device for freshwater prawn larvae is equipped with a container with all walls insulated, a breeding tank installed inside the container, a raw water tank installed inside the container, and an atmospheric temperature control device installed inside the container for controlling the atmospheric temperature inside the container, and is configured to circulate a temperature-controlled atmosphere inside the container, thereby at least maintaining the water temperature of the breeding tank at a constant temperature and minimizing the temperature distribution of the water temperature in the breeding tank. [Selected Figure] Figure 1

Description

The present invention relates to a breeding device for freshwater prawn larvae, and more specifically, to a device that can maintain the water temperature of a breeding tank for freshwater prawn larvae at a constant temperature while easily minimizing the temperature distribution of the water in the breeding tank, thereby reducing the operating costs of the breeding device for freshwater prawn larvae.

Macro shrimp are shrimp that live in river estuaries and freshwater and brackish lakes, and the larvae of macroprawns that live in river estuaries and brackish lakes grow in an environment influenced by seawater.

Macro shrimp hatch from eggs that have been spawned and spend their larval stage as plankton. These larvae undergo multiple metamorphoses and grow into baby shrimp after a period of about 20 to 25 days.

Since the larvae of the freshwater shrimp capture floating food but not sinking food, the larvae are raised by feeding them zooplankton and other foods.

When raising freshwater prawn larvae, very delicate management techniques are required, such as controlling the water temperature, the salinity of the breeding tank, feeding methods, and water quality of the breeding tank.

In particular, the optimum temperature range for the growth of freshwater prawn larvae in the breeding tank is narrow, and when there are large changes in the water temperature in the breeding tank or when there are large differences in the water temperature distribution in the breeding tank, the survival rate of the freshwater prawn larvae drops significantly or they may even die.

In addition, in order to control the water temperature in the breeding tank, temperature-controlled water is injected and the water in the breeding tank may be stirred to prevent large differences in the temperature distribution of the water in the breeding tank. In such cases, strong water currents are induced in the breeding tank, which can reduce the survival rate of the prawn larvae or even cause them to die. For this reason, water temperature management in the breeding tank and the method for doing so are extremely important factors in raising prawn larvae.

Conventionally, the method for controlling the water temperature in a breeding tank has been to inject pre-temperature-adjusted water directly into the tank or to circulate the water through pipes placed inside the tank. (See Patent Document 1.)

When this method of controlling water temperature in a breeding tank is adopted, there are cases where the water temperature in the breeding tank changes greatly, there are large differences in the temperature distribution of the water in the breeding tank, or strong water currents are induced in the breeding tank, resulting in a significant drop in the survival rate of the prawn larvae or even their death.

Furthermore, because heat flows out of the water in the breeding tank and out of the breeding tank, or heat flows into the breeding tank from outside, it is necessary to frequently inject pre-temperature-adjusted water into the breeding tank to maintain the water temperature in the breeding tank. This requires a lot of electricity to prepare this temperature-adjusted water, which increases the operating costs of the breeding apparatus for freshwater prawn larvae.

Japanese Patent Application Laid-Open No. 3-143334

The present invention was made to solve the problems mentioned above, and its objective is to provide a breeding device for freshwater shrimp larvae that reduces water temperature changes in the breeding tank, makes it difficult for temperature distribution in the water to occur in the breeding tank, and does not induce strong water currents in the breeding tank, thereby preventing the death of freshwater shrimp larvae and improving their survival rate.

Another object of the present invention is to reduce the operating costs of a breeding device for freshwater prawn larvae by minimizing the loss of heat from the water in the breeding tank to the outside of the breeding tank, or the inflow of heat from the water outside the breeding tank to the inside of the breeding tank.

In order to solve the above-mentioned problems, the invention according to the first aspect provides a rearing device for freshwater prawn larvae, which includes a container with all walls insulated, a rearing tank installed inside the container, a raw water tank installed inside the container, and an atmospheric temperature control device installed inside the container for controlling the atmospheric temperature inside the container, and by circulating the temperature-controlled atmosphere inside the container, at least the water temperature of the rearing tank is maintained at a constant temperature and the temperature distribution of the water temperature inside the rearing tank is minimized.

In addition, in the invention according to the second aspect, in the rearing device for freshwater prawn larvae of the invention according to the first aspect, a predetermined space is provided between the top, sides, and bottom of the rearing tank and the wall of the container, thereby positioning the rearing tank so that a temperature-controlled atmosphere can circulate on the top, sides, and bottom of the rearing tank.

In addition, the invention according to the third aspect is a rearing device for freshwater prawn larvae according to the invention according to the first or second aspect, in which the container is a marine container, and the upper surface, sides, and lower surface of the marine container are thermally insulated.

In addition, in a fourth aspect of the invention, in the rearing device for freshwater prawn larvae of the invention related to the first or second aspect, wheels are provided on the bottom of the container, making it movable.

In the rearing device for freshwater prawn larvae of the present invention, a temperature-controlled atmosphere is circulated inside the insulated container, making it possible to maintain a constant water temperature in the rearing tank and minimize the temperature distribution of the water in the rearing tank, while also making it possible to prevent the induction of strong water currents in the rearing tank. As a result, it is possible to prevent the death of freshwater prawn larvae and improve their survival rate.

Furthermore, in the rearing device for prawn larvae of the present invention, the loss of heat from the water in the rearing tank to the outside of the rearing tank, or the inflow of heat from the water outside the rearing tank to the inside of the rearing tank, is reduced, thereby significantly reducing the operating costs of the rearing device for prawn larvae.

FIG. 1 is a plan view showing the configuration of one embodiment of a rearing apparatus for prawn larvae according to the present invention. FIG. 2 shows a cross section AA of the rearing apparatus shown in FIG. FIG. 3 shows a cross section taken along line BB of the rearing apparatus shown in FIG. FIG. 4 shows a cross section taken along line CC of the rearing apparatus shown in FIG.

The following describes an embodiment of the present invention with reference to the drawings. Note that the embodiment of the present invention described here is merely an example of the present invention, and does not limit the scope of the invention.

Figures 1 to 4 are plan views showing the configuration of one embodiment of a rearing device 1 for prawn larvae according to the present invention. The rearing device 1 for prawn larvae is composed of a container 2, a rearing tank 3, a raw water tank 4, a feed culture tank 5, a water purification device 6, and an atmospheric temperature control device 7.

The container 2 is a container for storing each of the components that make up the rearing device 1 for prawn larvae. There are no particular limitations on the shape, but a rectangular parallelepiped shape is preferable for storing each of the components that make up the rearing device 1, and it can be constructed using steel or aluminum plates, wood, building boards, etc.

All walls of the container 2 (if the container 2 is a rectangular parallelepiped, the six walls, including the top, bottom and sides) are insulated. Insulation can be performed by attaching insulating sheets or boards to each wall, spraying insulating material, or applying insulating paint.

When constructing the container 2, it is possible to use an existing structure. For example, a conventionally used marine container may be used, and the above-mentioned insulation treatment may be applied to the six walls of the marine container, the top, bottom, and sides, to construct the container 2.

In addition, wheels (not shown) may be provided on the lower part of the container 2, for example on the bottom wall, to allow the container 2 to be easily moved.

The rearing tank 3 is an aquarium used for mating parent shrimp, for rearing parent shrimp carrying eggs, and for rearing hatched larvae of the shrimp. It has a rectangular parallelepiped shape, and the bottom and sides can be made of glass, plastic, etc., although it is not particularly limited.

The breeding tank 3 is made up of one or more tanks (in the example shown in FIG. 1, the breeding tank 3 is made up of five tanks), all of which are placed inside the container 2.

The breeding tank 3 is filled with breeding water and is connected to water supply and drainage pipes (not shown) for circulating the breeding water.

The raw water tank 4 is a tank for storing the breeding water to be supplied to the breeding tank 3, and is maintained at the same temperature as the water in the breeding tank 3. The raw water tank 4, like the breeding tank 3, may be rectangular in shape, with the bottom and sides made of glass, plastic, etc.

Rearing water whose temperature has been adjusted to a predetermined temperature is supplied to the raw water tank 4 from outside the container 2. Before being supplied to the raw water tank 4, the rearing water may be filtered and purified by a water purification device 6 before being supplied to the raw water tank 4. The raw water tank 4 is made up of one or more tanks (in the example shown in FIG. 1, the raw water tank 4 is made up of one tank), all of which are arranged inside the container 2.

In the raw water tank 4, aeration may be performed to increase the oxygen content in the breeding water and to adjust the salinity concentration in the breeding water.

The food culture tank 5 is a tank for cultivating zooplankton that serves as food for the prawn larvae, and the zooplankton cultivated here is fed to the prawn larvae.

In this embodiment, the food culture tank 5 is placed inside the container 2, but it may be installed outside the container 2, and food for the prawn larvae may be brought in from outside the container 2 and fed to the prawn larvae.

The water purification device 6 is a device for filtering and purifying the breeding water that has been adjusted to a predetermined temperature from outside the container 2, and the breeding water collected and filtered here is placed in the raw water tank 4. Note that this water purification device 6 can also be omitted.

The atmospheric temperature control device 7 is a device for controlling the atmospheric temperature inside the container 2, and is configured to suck in the atmosphere (air) inside the container 2, adjust the temperature of the sucked in atmosphere to a predetermined temperature, and then discharge it to circulate inside the container 2. The atmospheric temperature control device 7 is also connected to a heat exchanger installed outside the container 2 by piping (not shown).

The atmosphere (air) whose temperature is controlled by the atmosphere temperature control device 7 is circulated inside the container 2, particularly around the outer periphery of the breeding tank 3 and the raw water tank 4.

In particular, in order to allow a temperature-controlled atmosphere to circulate over the upper, side and bottom surfaces of the breeding aquarium 3 and the raw aquarium 4, the breeding aquarium 3 and the raw aquarium 4 are placed in the container 2 with a predetermined space provided between the upper, side and bottom surfaces of the breeding aquarium 3 and the raw aquarium 4 and the wall surfaces of the container 2 (the upper, side and bottom surfaces of the container 2) (see Figures 1 to 4).
Moreover, a plurality of atmosphere temperature control devices 7 may be installed to improve circulation of the temperature-controlled atmosphere inside the container 2. The breeding aquarium 3 and the raw aquarium tank 4 may be placed on a stand 8 as shown in Figures 1 to 4.

As described above, by positioning the breeding tank 3 so that a temperature-controlled atmosphere can circulate on the top, sides, and bottom of the breeding tank 3, it is possible to maintain the water temperature of the breeding tank 3 at a constant temperature and minimize the temperature distribution of the water temperature within the breeding tank 3.

In particular, since the specific heat of the circulating temperature-controlled atmosphere is extremely small compared to the specific heat of the breeding water, even if there is a difference in temperature between the circulating temperature-controlled atmosphere and the breeding water, the temperature change in the breeding water is extremely gradual, making it difficult for temperature distribution to occur in the breeding tank 3 and making it easier to maintain the breeding water at a constant temperature, and therefore not affecting the larvae.

As a result, convection of the breeding water is unlikely to occur in the breeding tank 3, and strong water currents are not induced, making it possible to prevent the death of the prawn larvae and improve their survival rate.

1 Rearing device 2 Container 3 Rearing tank 4 Raw water tank 5 Feed culture tank 6 Water purification device 7 Atmosphere temperature control device 8 Stand

Claims (4)

A container with insulated walls,
A breeding tank installed inside the container,
A raw water tank installed inside the container,
an atmospheric temperature control device that is installed inside the container and controls an atmospheric temperature inside the container;
A breeding device for freshwater shrimp larvae, characterized in that at least the water temperature in the breeding tank is maintained at a constant temperature and the temperature distribution of the water temperature in the breeding tank is minimized by circulating a temperature-controlled atmosphere inside the container.
2. The rearing device for prawn larvae as described in claim 1, characterized in that the rearing tank is arranged so that a temperature-controlled atmosphere can circulate on the upper, side and bottom surfaces of the rearing tank by providing a predetermined space between the upper, side and bottom surfaces of the rearing tank and the wall surface of the container.
The rearing apparatus for prawn larvae according to claim 1 or 2,
The container is a marine container, and the upper, side and lower surfaces of the marine container are thermally insulated.
The rearing apparatus for prawn larvae according to claim 1 or 2,
A rearing device for freshwater shrimp larvae, characterized in that wheels are provided on the bottom of the container to make it movable.