KR100310917B1 - Ammoniagas removal system of nursery - Google Patents

Abstract

The present invention is to raise the water of the aquaculture farm to 40 ℃-45 ℃ to vaporize the dissolved ammonia gas and the ammonia gas vaporized water is necessary for the growth of fish or shellfish using the waste heat (latent heat) generated in the tertiary heat exchanger It relates to ammonia gas removal systems in aquaculture farms that cool to temperature and feed them back to the farm.

Such a configuration of the present invention includes a primary heat exchanger provided with a heat exchanger for heat-exchanging water in aquaculture farms and water in a tank at 30 ° C. to 35 ° C. in an inner center of the main body; A secondary heat exchanger provided with a heat dissipation tube for heat-exchanging the heat-exchanged water at 30 ° C.-35 ° C. to 40 ° C.-45 ° C. by heat supplied from a cooling and heating device; A water tank provided to vaporize the ammonia gas while overflowing the heat-exchanged water at 40 ° C.-45 ° C .; And a third heat exchanger provided with a refrigerant pipe to heat the overflowed water to 20 ° C.-25 ° C. by cold air supplied from a cooling / heating device and supply it to the farm.

Description

Ammoniagas removal system of nursery

The present invention relates to a system for removing dissolved ammonia gas from aquaculture farms for farming various fish and shellfish, and more particularly, to evaporate ammonia gas dissolved in the water of aquaculture farms. The ammonia gas removal system of aquaculture farms uses the waste heat (latent heat) generated by the department to cool the fish or shellfish to the temperature necessary for growth to be supplied back to the farm.

In general, various fish and shellfish cultured in aquaculture farms excrete excrement containing ammonia, and the ammonia content contained in these excrements is dissolved in the water of the farm, which inhibits the growth of fish or shellfish farmed in the farm. In severe cases, various farmed fish and shellfish die, causing enormous damage to fish farms.

Therefore, it is essential that aquaculture conditions of various fish and shellfish in aquaculture farms remove dissolved ammonia gas generated by fish or shellfish excretion to promote the growth of fish and shellfish and to have a high quality meat.

The conventional method for removing ammonia gas to meet these requirements is to make two or more reservoirs at least two times larger than the size of the farm in the vicinity of the farm and circulate water in the farm to naturally vaporize the ammonia gas. Or dilution by obtaining fresh water.

However, in the above method, the area of the reservoir for removing ammonia gas is much larger than that of fish farms and shellfish farms, resulting in loss of economical efficiency and difficulty in securing the reservoir. It was not enough to remove all ammonia gas.

Therefore, in order to solve the above problems, digging groundwater near the farm and pumping the groundwater directly to the farm, diluting the water in the farm where the ammonia gas is dissolved with the water of the groundwater to reduce the ammonia gas concentration. At the same time, the other side of the farm is using a method for draining the ground water as much as the water is supplied.

However, since the groundwater maintains a temperature of 8 ° C-14 ° C, if it is continuously supplied to the farm, the temperature of the farm keeps the temperature of the groundwater, which does not maintain the temperature of 15 ° C-20 ° C necessary for fish and shellfish to grow. There was a problem that inhibits the growth of fish and shellfish.

In addition, the water dissolved in the ammonia gas drained from the other side of the farm is released to the soil immediately without going through a separate wastewater treatment facility, which may cause soil pollution and water pollution.

The present invention has been invented to solve the above problems, the object is to remove the dissolved ammonia gas generated by the excreta of various fish or shellfish farmed in the farm and to supply the ammonia gas removed water back to the farm By raising the temperature of the water supplied to keep the temperature of 15 ℃ -20 ℃ suitable for fish or shellfish growth, it promotes the growth of fish and shellfish and has high quality meat so that the income of fish farms can be increased. To provide ammonia gas removal system.

1 is a schematic view showing a farm ammonia gas removal system of the present invention.

Figure 2 is a block diagram showing ammonia gas removal process using aquaculture ammonia gas removal system of the present invention.

※ Explanation of main parts of drawing ※

A: body P: pump

10: primary heat exchanger 11: heat exchanger

12,13: Euro 14,16: water supply

15,17: Screen network 18,19: Water supply passage

20: secondary heat exchanger 21: heat dissipation tube

30: tank 31: drip tray

32: pipe 40: duct

41: fan 50: 3rd heat exchanger

51 refrigerant tube 52 drain tube

53: valve 60: cooling, heating device

Hereinafter, the technical features of the present invention will be described in detail.

The present invention is a conventional cooling and heating device provided so that heat is circulated through the heat discharge tube and cold air is circulated in the refrigerant tube, wherein the water in the farm and the water in the tank are heat-exchanged at 30 ° C. to 35 ° C. in the inner center of the main body. A primary heat exchanger provided with a heat exchanger; A secondary heat exchanger provided with a heat dissipation tube for heat-exchanging the heat-exchanged water at 30 ° C.-35 ° C. to 40 ° C.-45 ° C. by heat supplied from a cooling and heating device; A water tank provided to vaporize the ammonia gas while overflowing the heat-exchanged water at 40 ° C.-45 ° C .; And a third heat exchanger provided with a refrigerant pipe to heat the overflowed water to 20 ° C.-25 ° C. by cold air supplied from a cooling / heating device and supply it to the farm.

In addition, the heat exchanger of the present invention is characterized in that each of the flow path is provided so that the water pumped from the pump and the water recovered from the water tank proceeds up and down repeatedly in a reverse direction to each other, the upper and lower portions of the primary heat exchanger 30 ℃ -It is characterized in that the water supply unit is provided with each screen net is provided so that the water heat exchanged to 35 ℃ evenly supplied to the secondary and tertiary heat exchanger.

In addition, the heat dissipation tube provided in the secondary heat exchanger of the present invention is arranged in a zigzag to increase the heat exchange efficiency of water, the temperature of the heat flowing therein is characterized in that the temperature of 60 ℃-70 ℃, the water tank is over the outer periphery A drip tray is provided to receive the flow of water, and one side of the drip tray is provided with a pipe connected to the inlet of the flow path.

And the upper part of the tank is characterized in that the duct is provided with a fan on one side to collect the ammonia gas vaporized to discharge to the destination, the heat discharge tube provided in the third heat exchanger is arranged in a zigzag to increase the heat exchange efficiency of water The temperature of the cold air flowing therein is characterized by being 5 ° C or less.

The present invention having such features will be described in more detail with reference to the accompanying drawings as follows.

1 is a schematic view showing aquaculture ammonia gas removal system of the present invention, Figure 2 is a block diagram showing ammonia gas removal process using aquaculture ammonia gas removal system of the present invention.

The aquaculture farm ammonia gas removal system of the present invention is 30 ° C-35 of water in the aquaculture farm 70 to maintain 15 ° C-20 ° C in the center of the body (A) and water of the water tank 30 to maintain 40 ° C-45 ° C The primary heat exchanger 10 is provided with a heat exchanger 11 for heat exchange at ℃ ℃, which is the water of the farm (hereinafter referred to as water) and aquaculture farm pumped by the pump (P) in the primary heat exchanger (10) The heat exchanger 11 provided with each flow path 12 and 13 is provided so that the water collect | recovered from the water tank 30 may repeat up and down several times in a reverse direction mutually.

In addition, the upper and lower portions of the primary heat exchanger 10 are heated with heat exchanged at 30 ° C. to 35 ° C. to the heat dissipation pipe 21 and the refrigerant pipe 51 of the secondary and tertiary heat exchangers 20 and 50. Water supply parts 14 and 16 having predetermined spaces to be evenly supplied and provided with screen screens 15 and 17 are formed.

In addition, the upper portion of the first heat exchanger 10 exchanges the heat-exchanged water at 30 ° C.-35 ° C. to 40 ° C.-45 ° C. by heat to maintain 60 ° C.-70 ° C. supplied from the cooling / heating device 60. The secondary heat exchanger 20 is provided with a heat dissipation tube 21 connected to a cooling / heating device 60 to heat the heat dissipation tube 21. The heat dissipation tube 21 is arranged in a zigzag and flows into the heat to increase the heat exchange efficiency of water. Maintain the temperature of 60 ℃-70 ℃.

And the upper part of the secondary heat exchange unit 20 is provided with a water tank 30 for vaporizing ammonia gas while overflowing the water heat exchanged in the secondary heat exchange unit 20 to 40 ℃-45 ℃, this water tank 30 The top of the outer periphery of the) is provided with a drip tray 31 to receive the overflowed water, and one side of the drip tray 31 is provided with a pipe 32 connected to the inlet side of the flow path 12 of the heat exchanger (11).

On the other hand, the upper portion of the water tank 30 is provided with a duct 40 is installed in the fan 41 is installed on one side of the inside of the ammonia gas that is overflowed and discharged to the destination (ammonia gas removal equipment (not shown)).

In addition, the lower portion of the primary heat exchange unit 10 is heat-exchanged to 20 ℃-25 ℃ by the cold air of 5 ℃ or less supplied from the cooling and heating device 60 to supply back to the farm 70 A tertiary heat exchanger unit 50 having a coolant tube 51 is provided, and the coolant tube 21 is arranged in a zigzag manner in order to increase the heat exchange efficiency of water, and the drain tube 52 having the valve 53 at the bottom thereof. Is installed.

Referring to the operation and the embodiment of the present invention configured as described above are as follows.

The present invention will first be described with respect to the water of the farm 70. The various fish and shellfish cultured in the farm 70 are excreted while growing, and the excrement contains ammonia gas, so that the ammonia gas is dissolved in the water of the farm and adversely affects the growth of fish and shellfish.

Therefore, the water in the aquaculture farm 70 in which the ammonia gas is dissolved may promote the growth of fish and shellfish by removing the ammonia gas.

And the water temperature of the farm 70 is 15 ℃-20 ℃, the water passing through the first heat exchange unit 10 is heat exchanged to 30 ℃-35 ℃, the water passed through the secondary heat exchange unit 20 is Heat exchange at 40 ℃ -45 ℃ In addition, the temperature of the heat blown from the cooling / heating device 60 to the heat dissipation pipe 21 is 60 ° C-70 ° C, and the temperature of the cold air blown into the refrigerant pipe 51 is 5 ° C.

As shown in FIG. 1 and FIG. 2, the water of the aquaculture farm 70 in which ammonia gas is dissolved is supplied to the inlet of the flow path 13 using the pump P, and the supplied water is supplied to the pump P. By the continuous operation, the water supply path 18 is supplied to the water supply unit 14 provided at the upper portion of the primary heat exchanger unit 10 by repeating the flow channel 13 up and down several times.

And the water overflowed from the water tank 30 is supplied to the inlet side of the other flow path 12 through the pipe 32 and proceeds in the direction opposite to the direction of the water in the farm 50, the primary heat exchange unit 10 It is supplied to the water supply unit 16 provided in the lower portion of the) is supplied to the third heat exchange unit (50).

In this way, the water of the farm 70 holding 15 ° C.-20 ° C. and the overflowed water of the water tank 30 holding 40 ° C.-45 ° C. cross each other along each of the flow paths 12, 13. While proceeding in the reverse direction, the water passing through each of the flow paths 12 and 13 is heat-exchanged at 30 ° C. to 35 ° C. while mutually exchanging heat due to their temperature difference.

At this time, the water supplied to the water supply unit 14 by heat exchange at 30 ° C. to 35 ° C. gradually cools from the bottom of the secondary heat exchange part 20 to the upper part while passing through the screen net 15, thereby cooling and heating the device 60. ) Is second heat exchanged to 40 ° C-45 ° C by heat released from the heat of 60 ° C-70 ° C circulating the heat discharge tube (21).

And the water maintaining the second heat exchanged 40 ℃-45 ℃ is continuously introduced into the water tank 30 through the water supply passage 19 and the introduced water is overflowed at the top of the water tank 30 at the same time Only the purified water (water vaporized with ammonia gas) while vaporizing ammonia gas is received by the drip tray 31.

Thereafter, the purified water received by the drip tray 31 is supplied to the flow passage 12 of the heat exchanger 11 provided in the primary heat exchange unit 10 through the pipe 32 and the flow passage 13 as described above. The heat dissipation by the water in the farm 70 of 15 ℃-20 ℃ proceeding in the reverse direction to the heat exchange to 30 ℃-35 ℃ to the water supply unit 16 provided in the lower portion of the primary heat exchange unit (10) The water is gradually supplied from the upper portion to the lower portion of the tertiary heat exchange unit 30 while passing through the screen net 17, and is supplied from the cooling / heating device 60 to circulate the refrigerant pipe 51 at 5 ° C or lower. The third heat exchange to 20 ℃-25 ℃ by the cold air discharged from the is obtained back into the farm 70 through the drain pipe (52).

At this time, the cold air of 5 ° C or less flowing through the refrigerant pipe 51 is heated to the third heat exchange, the heat is recovered to the cooling and heating device 60 and 60 ° C-70 ° C to supply to the heat dissipation pipe 21 to heat When it is generated, it has a preheating effect, thereby saving energy.

However, the ammonia gas that is overflowed at the upper portion of the water tank 30 and vaporized at the same time is collected into the duct 40 provided at the upper portion of the water tank 30, and the air pollution prevention facility is operated by the operation of the fan 41 installed at one side thereof. It is sent to (not shown) to remove ammonia gas from this facility.

The purified water, which is heat-exchanged at 20 ° C.-25 ° C. and obtained into the aquaculture farm 70, is drained to the aquaculture farm 70 and simultaneously cooled to maintain 15 ° C.-20 ° C. Therefore, the water temperature of the farm 70 is to maintain 15 ℃-20 ℃ suitable for the growth of fish oil and shellfish.

In addition, the heat exchange temperature control of the first and second and third and third heat exchanger 10, 20, 50 of the present invention can be freely by adjusting the speed of the water, each heat exchanger 10 mentioned above Temperature control of (20) (50) can be made simple as needed.

The operation of the aquaculture farm ammonia gas removal system of the present invention as described above measures the dissolved ammonia gas level in the farm to frequently remove the ammonia gas when the fish or shellfish is not suitable for growth.

Therefore, the aquaculture farm ammonia gas removal system of the present invention can be economically installed by simply installing on one side of the farm without the need for a separate installation space to remove the ammonia gas, and also promote the growth of fish and shellfish and obtain high quality meat. There is this.

The aquaculture farm ammonia gas removal system of the present invention as described above can be easily installed on one side of the farm to remove dissolved ammonia gas as needed to promote the growth of fish and shellfish grown in the farm, and obtain high quality meat. It is effective to increase income.

In addition, the aquaculture plant ammonia gas removal system of the present invention is composed of the structure of the primary and secondary and tertiary heat exchanger, and the tank and the duct is easy to manufacture and inexpensive production cost is economical and cool the waste heat (latent heat) generated during the third heat exchange There is a distinctive effect of saving energy by recovering and using the heating system.

Claims (7)

In the conventional air-conditioning and heating device (60) provided that heat is circulated through the heat dissipation pipe (21) and cold air is circulated through the refrigerant pipe (51), A primary heat exchanger (10) provided with a heat exchanger (11) for heat-exchanging water in the farm (70) and water in the water tank (30) at 30 ° C-35 ° C in the inner center of the main body (A); A secondary heat exchanger 20 provided with a heat dissipation tube 21 for heat-exchanging the heat-exchanged water at 30 ° C.-35 ° C. to 40 ° C.-45 ° C. by the heat supplied from the cooling / heating device 60; A water tank 30 provided to vaporize the ammonia gas while overflowing the heat-exchanged water at 40 ° C.-45 ° C .; A third heat exchanger (50) provided with a refrigerant pipe (51) to heat the overflowed water to 20 ° C.-25 ° C. by cold air supplied from a cooling / heating device (60) and to supply it to the farm (70); Ammonia gas removal system of the farm, characterized in that consisting of. The heat exchanger (11) according to claim 1, wherein each of the heat exchangers (11) so that the water pumped from the pump (P) and the water recovered from the water tank (30) proceeds repeatedly in the opposite direction. Ammonia gas removal system of aquaculture farms, characterized in that According to claim 1, wherein the upper and lower portions of the primary heat exchanger 10, each screen net so that the water heat-exchanged at 30 ℃-35 ℃ uniformly supplied to the secondary and tertiary heat exchange unit (20, 50) (15) (17) The ammonia gas removal system of the farm, characterized in that the water supply unit 14, 16 is provided. The heat dissipation tube 21 provided in the secondary heat exchange unit 20 is arranged in a zigzag to increase the heat exchange efficiency of water, and the temperature of the heat flowing therein is 60 ° C. to 70 ° C. Aquaculture ammonia removal system. The water tank (30) of claim 1, wherein the water tank (30) is provided with a drip tray (31) to receive the overflowed water on the outer periphery and the pipe (32) connected to the inlet side of the flow path (12) on one side of the drip tray (31). Ammonia gas removal system of the farm, characterized in that the prepared. The ammonia gas removal system of aquaculture plants according to claim 1, characterized in that a duct (40) having a fan (41) is provided on one side of the water tank (30) to collect the vaporized ammonia gas and discharge it to a destination. The method of claim 1, wherein the refrigerant pipe 51 provided in the tertiary heat exchange unit 50 is arranged in a zigzag to increase the heat exchange efficiency of water and the temperature of the cold air flowing therein is 5 ° C or less. Ammonia gas removal system.