KR20190114067A - An apparatus for adjusting temperature of sea water supplied to a fish farm - Google Patents

Abstract

The present invention relates to an apparatus for controlling a temperature of supplied seawater of a fish farm, which comprises a heating apparatus (100) for heating seawater of a plurality of supply pipes (5) and a seawater supply pipe (5) for supplying the seawater to a plurality of fish farming tanks (50) by drawing the seawater through a raw water supply pipe (1). The heating apparatus (10) includes: a case (11) for accommodating a seawater supply pipe (5) to pass therethrough; a heating plate (20) disposed at a lower side of the seawater supply pipe (5) in the case (11); a heater (30) disposed in a recess part (25) formed on an upper side of the heating plate (20); and an insulation material (40) disposed to surround the seawater supply pipe (5) and the heating plate (20). According to the present invention, an electric heating pipe is installed adjacent to introduced seawater supply pipes to heat seawater at a predetermined appropriate temperature while flowing through the seawater supply pipes, such that the seawater with a controlled temperature is directly supplied to a fish farming tank to have a simple structure, thereby lowering installation costs. Also, a temperature is easily controlled and an insulator is installed around the seawater supply pipes to increase the energy efficiency.

Description

Fish farm supply seawater temperature controller {AN APPARATUS FOR ADJUSTING TEMPERATURE OF SEA WATER SUPPLIED TO A FISH FARM}

The present invention relates to aquaculture farm supply seawater temperature control device for controlling the temperature of the seawater to be supplied to the farm, in particular, by rapidly raising the seawater supplied to the farm to the appropriate growth temperature of the cultured fish or shellfish It relates to aquaculture farm-supplied seawater temperature control system that prevents and enables sustainable growth.

In general, most aquaculture organisms are affected by physiological metabolism depending on the water temperature as the altered animal, and grows rapidly at high water temperature in the adaptive temperature range. For example, trout or salmon belonging to cold water fish live at 0-20 degrees, but grow well above 15 degrees, while carp and eel, which are hot water fish, grow well at high temperatures of 25-26 degrees.

In winter, on the west coast of Korea, the average seawater temperature from December to March decreases below 10 degrees. If the low water temperature continues below 4 degrees, farmed fish dies or disease occurrence increases due to weakened immunity. This is very important.

Domestic farms mainly draw seawater or groundwater and supply them to a plurality of aquaculture tanks, and heat up the seawater or groundwater supplied to the aquaculture tanks.

As an example of the prior art for controlling the water temperature of aquaculture farms, Korean Patent Laid-Open Publication No. 10-2001-0025134 (published April 06, 2001) includes a first method configured to heat-exchange wastewater and raw water supplied to each other. A heat exchanger, a second heat exchanger configured to discharge raw water passing through the first heat exchanger from the condenser of the heating apparatus and to the aquaculture farm, and aquaculture water passing through the first heat exchanger to supply the heat to the evaporator of the heating apparatus. Disclosed is a water temperature control system for aquaculture farms consisting of a third heat exchanger configured to be discarded afterwards.

However, as described above, the structure for adjusting the water temperature of the farm by providing heat exchangers is not only difficult to apply to a system that draws seawater and supplies it directly to the tank, because the facility cost burdened by the aquaculture farm is too large. There was a problem of low heat recovery efficiency compared to facility cost.

Korean Laid-Open Patent Publication No. 10-2001-0025134 (published April 06, 2001)

An object of the present invention is to efficiently supply the seawater of the controlled temperature to the aquaculture tanks by directly heating the seawater supply pipes for introducing a plurality of aquaculture tanks to the aquaculture tanks in order to solve the problems of the prior art described above It is to provide aquaculture farm supply seawater temperature control device of the improved structure to control the seawater temperature.

In order to achieve the above object, aquaculture farm supply seawater temperature control apparatus according to the present invention

By installing an electric heating tube adjacent to the inlet seawater supply pipes according to the present invention, the seawater flows through the supply pipe and is configured to supply seawater regulated by aquaculture tanks by heating to a predetermined temperature at a predetermined temperature, so that the structure is easily installed. The cost can be lowered, the temperature can be easily adjusted, and energy efficiency is improved by installing insulation around the seawater supply pipe.

1 is a plan view schematically showing a configuration for temperature control of the aquaculture supply seawater according to the present invention.
Figure 2 is a schematic perspective view showing the structure of the seawater heating apparatus of FIG.
3 is a schematic longitudinal sectional view of the heating apparatus of FIG.
4 is a cross-sectional view of a heating apparatus according to a modification of the present invention.

Hereinafter, with reference to the accompanying drawings showing an embodiment of aquaculture farm supply seawater temperature control apparatus according to the present invention will be described in more detail the present invention.

1 to 3, the farm supply seawater temperature control apparatus according to the present invention is for branching from the co-distributor (2), the common distributor (2) for drawing and storing and distributing seawater through the raw water supply pipe (1) A plurality of supply pipes 5, a heating device 10 for heating the seawater of the plurality of supply pipes 5 branched from the co-distributor 2, and the seawater heated up to an appropriate temperature by the heating device to form a tank (50) It includes a sea water supply pipe (5 ') for supplying).

Sea water is stored in the co-distributor 2 through the raw water supply pipe 1 by a pump not shown in the drawing, and the sea water into a supply pipe 5 for supplying the seawater heated to an appropriate temperature to the aquaculture tanks 50, respectively. Distribute and supply The supply pipes 5 drawn out from the co-distributor 2 are equipped with a temperature sensor 6 to check the temperature of the seawater supplied.

The open / close valve 8 and the pressure in each of the supply pipes 5 arranged to collect seawater heated to an appropriate temperature by the heating device 10 in the co-distributor 7 and then directed to the respective culture tanks 50. It is preferable that a control valve 9 is provided, for example, to interrupt the supply of seawater to the closed aquaculture tanks 50 and to allow the flow rate of the seawater to be supplied to each of the aquaculture tanks to regulate the pressure constantly.

The sea water supply pipe 5 is heated while passing through the heating device 10 according to the present invention is heated to a predetermined temperature range.

The heating apparatus 10 includes a case 11 accommodating the plurality of sea water supply pipes 5, a hot plate 20 and a hot plate 20 disposed below the sea water supply pipe 5 in the case 11. For example, the heater 30 includes a heater 30, such as a heating wire, and a heat insulating material 40 disposed to surround the supply pipe 5 and the hot plate 20.

The hot plate 20 is supported at a position spaced apart from the bottom of the case 11 by the bracket 13, and the seawater supply pipes 5 in the heating device 10 are also attached to the bracket 15. It is preferably supported by.

The hot plate 20 may be arranged in a zigzag manner at a right angle to the seawater supply pipe 5 in the embodiment in which the heater 30 is shown.

The temperature sensor 12 is also installed in each of the seawater supply pipes 5 in the heating apparatus 10 to check the temperature of the seawater in each of the supply pipes heated by the heater.

This is because the temperature of the seawater supply pipe 5 drawn from the common distributor 2 on the front side of the heating device 10 is checked by the temperature sensor 6 and by the heater 30 in the heating device 10. The elevated temperature in each heated seawater supply pipe 5 is checked by the temperature sensor 12 to determine whether it is included in a preset temperature range so as to control the operation of the heater 30. In addition, a temperature sensor 17 is also installed in the seawater supply pipe 5 downstream of the heating device 10 to check the temperature of the seawater heated by the plurality of seawater supply pipes 5 in the heating device, thereby heating the heater 30. ) Can be used to check and determine whether there are no problems with piping or insulation.

The heat insulating material 40 is a bottom surface of the hot plate 20 and the upper side of the sea water supply pipe 5, for example, by using a heat insulating material to reflect the heat energy generated from the heater to the sea water supply pipe, and the heat insulating material outside the reflective heat insulating material It is preferable that the heat energy of the heater can be used to heat the seawater in the seawater supply pipe so as to efficiently use the energy.

Seawater flow rate calculated from the temperature detected by the temperature sensor 6 provided in the seawater supply pipe 5 adjacent to the common distributor 2, the cross-sectional area of each supply pipe 5, and the flow rate of the seawater passing through the supply pipes; By calculating the heat energy required to increase the temperature from the temperature sensed by the temperature sensor 6 to a target temperature, and by operating the heater 30 to supply the heat energy required for the temperature increase, the temperature control according to aquaculture organisms is easily performed. You can do it.

Each of the seawater supply pipes 5 passing through the heating device 10 is collected in a collection tank 7 and connected to each of the plurality of aquaculture tanks 50 so as to directly supply seawater, and the seawater supply pipes 5 are It is preferable that the check valve 8 and the pressure regulating valve 7 are installed to adjust the flow rate of the seawater supplied.

In addition, it is preferable that the collection tank 7 is provided with a temperature sensor to check whether the temperature of the final seawater collected through the heating device 10 is within an appropriate temperature range and reflect the control in the heater 30.

In the embodiment of FIG. 2, the heater 30 is reciprocally arranged in a zigzag manner with one heating wire, but as a modification, as shown in FIG. 4, the heater 30 is parallel to the seawater supply pipe 5. The heaters may be arranged and configured to operate the plurality of heaters individually or in a bundle so as to efficiently control the temperature.

In addition, the heat insulating material 40 is reflected on the bottom surface of the hot plate 20 and the upper side of the seawater supply pipe 5, for example, the heat energy generated from the heater by the heat-resistant reflective insulation 60 is reflected by the reflective insulation 60 Facing the seawater supply pipe, and filling the heat insulating material 40 generally used in the outer space of the reflective insulation material so that the heat energy of the heater can be used to heat the seawater in the seawater supply pipe to use the energy efficiently. Do.

The present invention can be used to raise the temperature of the seawater supplied from the farms supplied to each culture tank of the farms by raising the seawater to an appropriate temperature for the aquaculture organisms in winter.

1: raw water supply pipe 2: joint distributor
5: supply pipe 6, 12: temperature sensor
10: heating device 11: case
13, 15: bracket 20: hot plate
25: groove 30: heater
40: insulation 50: aquaculture tank
60: reflective insulation

Claims (5)

A plurality of supply pipes 5 for drawing seawater through the raw water supply pipe 1 and supplying seawater to each of the plurality of aquaculture tanks 50, and a heating device 10 for heating seawater of the seawater supply pipe 5; In the farm supply seawater temperature control device provided,
The heating device 10 includes a case 11 accommodating the seawater supply pipes 5, a hot plate 20 disposed below the seawater supply pipe 5 in the case 11, and the hot plate 20. Aquaculture plant supply seawater temperature control device comprising a heater (30) disposed in the groove portion 25 formed on the upper side and a heat insulating material (40) arranged to surround the supply pipe (5) and the hot plate (20). The method of claim 1,
The heating device 10 includes a temperature sensor 6 mounted on each of the seawater supply pipes 5 branched from the co-distributor 2 through the raw water supply pipe 1 in front thereof, and the seawater in the heating device 10. Aquaculture plant supply seawater temperature control device, characterized in that to control the operation of the heater 30 by the temperature information from the temperature sensor 12 installed in each of the supply pipe (5). The method of claim 1,
The heater 30 is aquaculture farm supply seawater temperature control device, characterized in that arranged in a zigzag form, at a right angle to the seawater supply pipe (5). The method of claim 1,
The heater 30 is a plurality of farms supplying seawater temperature control device, characterized in that arranged in parallel with the seawater supply pipe (5) to selectively control the plurality of heaters at least one by one. The method of claim 1,
The heat insulating material 40 is aquaculture farm supply seawater temperature control device further comprises a heat-resistant reflective insulating material (60) disposed on the bottom of the hot plate 20 and the upper side of the sea water supply pipe (5).

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