KR102190368B1 - System for converting cooling and heating using seawater heat pump - Google Patents

Abstract

The present invention relates to a cooling/heating switching system using a seawater heat pump, and more particularly, a seawater heat pump that controls and supplies the temperature of water to be stored in a facility such as a water tank by using seawater as a heat source of the heat pump. It relates to the used cooling and heating switching system.
The cooling/heating switching system using the seawater heat heat pump of the present invention recovers heat from seawater and cools or heats facilities including a water tank, so facility management is easy and costs can be reduced.
In addition, the cooling/heating switching system using the seawater heat heat pump of the present invention has the advantage of easy facility temperature control since cooling and heating can be easily switched according to the season or environment.
In addition, the cooling/heating switching system using the seawater heat heat pump of the present invention can provide a comfortable environment for fish and shellfish to inhabit because foreign substances are filtered and seawater with an increased amount of dissolved oxygen is supplied to the tank in which seawater is stored. There is an advantage.

Description

System for converting cooling and heating using seawater heat pump}

The present invention relates to a cooling/heating switching system using a seawater heat pump, and more particularly, a seawater heat pump that controls and supplies the temperature of water to be stored in a facility such as a water tank by using seawater as a heat source of the heat pump. It relates to the used cooling and heating switching system.

A heat pump is a cooling/heating device that transfers a low-temperature heat source to a high temperature or a high-temperature heat source to a low temperature by using the heat generation or condensation heat of a refrigerant. have.

When water is used as a heat source for a heat pump, water with a water temperature lower than the ambient temperature can be used for cooling and water with a water temperature higher than the ambient temperature can be used for heating, so water heat is very good as a heat source for the heat pump.

In order to use water (seawater, river water) as a heat source for a heat pump, it is necessary to install a filter and heat exchanger to facilitate maintenance of the heat pump without being affected by the water quality or properties. The heat exchanger should be manufactured. In addition, in the system using water heat, the water intake facility is very important, and inspection and management measures are required to secure the design flow rate. By installing a filter for the water used for heat exchange, it is possible to prevent foreign substances such as organisms from sticking to the heat exchanger plate and reducing heat exchange efficiency, but power is required for the maintenance and operation of the filter.

On the other hand, most farms and raw fish stores adopt a business method in which a large amount of fish and shellfish is stored at high density along with water in a tank that forms a relatively narrow space, and then taken out and sold when necessary.

When a large amount of fish and shellfish is stored at high density in a tank forming a narrow space, when a large amount of fish and shellfish is stored, dissolved oxygen contained in water is rapidly consumed, and at the same time, various foreign substances, proteins, ammonia, and Nitrogen components accumulate in the water at a high concentration within a short period of time, and as a result, the quality of the water in the tank deteriorates rapidly, which not only adversely affects the growth conditions and freshness of fish and shellfish, but also causes a serious situation where fish and shellfish die in severe cases. do. This phenomenon is closely related to the temperature in the tank.

The fish and shellfish stored in the tank must be maintained at an appropriate water temperature according to the characteristics of fish and shellfish.For cold water fish, use a cooler to cool the stored water, and for temperate or subtropical fish, use an electric heater to raise the water temperature. It is common to raise the water temperature. In particular, in the summer, the water temperature in the tank rises due to the high external temperature, and fish that require a water temperature of around 10 degrees Celsius will die. Also in winter when the outside temperature is low, the water temperature in the tank will drop below zero. This is an important part of management.

However, in order to lower the water temperature of 1 degree Celsius, it is inevitable to operate the cooler for a long time, and at this time, the operation of the compressor generates noise and vibrations and hot air, thereby hindering the living environment. In addition, since Freon gas used as a refrigerant pollutes the atmospheric environment and destroys the ozone layer, there is an urgent need for an alternative device. In addition, the electric heater method, which is used as a method of raising the water temperature stored in the water tank in winter, has a difference in water temperature around the heater. As it is severe, it puts considerable stress on fish that are very sensitive to water temperature, and the consumption of electricity cannot be overlooked. In addition, conventional coolers and heaters are inconvenient to be repeatedly installed and removed depending on the season.

Republic of Korea Utility Model Publication No. 20-0381865: Water tank cold and hot water machine Republic of Korea Patent Publication No. 10-1812976: Seawater heat heat pump device and method for simultaneously performing freshwater production and cooling and heating

The present invention was created to improve the above problems, and a cooling/heating switching system using a seawater heat pump that is easy to manage and eco-friendly because it is possible to control the temperature of water to be stored in a facility such as a water tank using a heat source Want to provide.

A cooling/heating switching system using the seawater heat heat pump of the present invention for achieving the above object comprises: a water storage tank storing water for supply to facilities; A heat pump unit connected to the water storage tank and configured to heat or cool the water stored in the water storage tank according to the circulation direction of the refrigerant exchanged with seawater; And a water circulation unit for supplying water heated or cooled by the heat pump unit to the facility or circulating the water of the facility to the heat pump unit.

The heat pump unit includes a first seawater intake pipe for sucking seawater from the sea, a first chamber in which seawater introduced from the first seawater intake pipe is stored, and the refrigerant and the seawater are heat-exchanged by being located in the first chamber. A first heat exchange unit including a first heat exchanger and a first seawater discharge pipe flowing into the first chamber to discharge seawater heat-exchanged with the refrigerant to the sea; A second chamber into which water flows from the water storage tank; a second heat exchanger located in the second chamber to exchange heat with the water introduced into the second chamber; and water heat-exchanged with the refrigerant in the second chamber A second heat exchange unit including first and second water transfer main pipes connected to the water circulation unit to discharge the water to the water storage tank or the facility or to suck water in the water storage tank to the second chamber; And a first refrigerant circulation pipe connecting each side of the first heat exchange part and the second heat exchange part, and a second refrigerant circulation pipe connecting each other side of the first heat exchange part and the second heat exchange part.

The cooling/heating switching system using the seawater heat heat pump of the present invention includes a second seawater intake pipe extending from the sea and inhaling seawater, and a predetermined time so that foreign matter introduced together with seawater through the second seawater intake pipe is deposited downward. A seawater purification tank in which seawater introduced from the second seawater intake pipe is stored, and seawater from which the foreign substances are removed from the seawater purification tank is supplied to the water storage tank. 2 A seawater purification unit including a seawater discharge pipe; further comprising, the water stored in the water storage tank may be seawater introduced from the seawater purification tank.

The seawater purification unit further includes a dissolved oxygen amount raising unit for increasing the amount of dissolved oxygen in seawater flowing into the seawater purification tank, and the dissolved oxygen amount raising unit includes the second seawater intake pipe extending vertically into the seawater purification tank. A seawater oxygen dissolving pipe that extends vertically so that the end side is accommodated in the inside and has an inner diameter larger than the second seawater intake pipe, and the lower part is submerged in the seawater introduced into the seawater purification tank, and the seawater oxygen dissolution pipe inside and outside the seawater oxygen dissolution pipe An oxygen supply pipe for introducing air and an oxygen supply pipe that is installed to be arranged in the longitudinal direction of the seawater oxygen dissolution pipe in the hollow of the seawater oxygen dissolution pipe, and is formed through the seawater to pass through, and when the seawater passes through, the supply pipe air and the seawater It is provided with a plurality of dissolution inducing members formed through each other in different positions and shapes to induce and stir.

The plurality of solubility inducing members have a first dissolution inducing member formed with a first seawater through hole penetrating therein so as to repeat a decrease and increase in the distance of the inner circumferential surface to the outer circumferential surface toward the circumferential direction, and the first dissolution inducing member A plurality of second seawater that is installed at a location spaced apart in the longitudinal direction of the seawater oxygen dissolving pipe, and the outer diameter decreases and increases repeatedly along the circumferential direction, so that the seawater passes through the seawater separated from the inner circumferential surface of the seawater oxygen dissolution pipe. A second dissolution guide member may be provided with a through hole formed therein and a plurality of auxiliary protrusions protruding in the seawater inflow direction on one surface of the seawater inflow direction to induce mixing of the seawater and air.

In addition, the plurality of dissolution inducing members extend in one direction and are penetrated by a plurality of first extension ribs extending in parallel with each other, and a plurality of second extension ribs intersecting with the first extension rib and extending in parallel with each other. Each formed in the form of a mesh with a ball, wherein the first extension rib or the second extension rib is installed in the sea oxygen dissolution pipe to cross the first extension rib or the second extension rib of the dissolution inducing member adjacent to each other. It is desirable.

The oxygen supply pipe penetrates each center of the plurality of dissolution inducing members so that a region in which the seawater and air discharged from the oxygen supply pipe are mixed within the seawater oxygen dissolution pipe is secured, and the length of the seawater oxygen dissolution pipe It is preferable that a plurality of air discharge holes are formed on the outer circumferential surface of the outer circumferential surface that extend parallel to the direction so as to be accommodated in the seawater oxygen melting pipe and discharged to the seawater oxygen melting pipe.

The cooling/heating switching system using the seawater heat heat pump of the present invention recovers heat from seawater and cools or heats facilities including a water tank, so facility management is easy and costs can be reduced.

In addition, the cooling/heating switching system using the seawater heat heat pump of the present invention has the advantage of easy facility temperature control since cooling and heating can be easily switched according to the season or environment.

In addition, the cooling/heating switching system using the seawater heat heat pump of the present invention can provide a comfortable environment for fish and shellfish to inhabit because foreign substances are filtered and seawater with an increased amount of dissolved oxygen is supplied to the tank in which seawater is stored. There is an advantage.

1 is a diagram of a cooling/heating switching system using a seawater heat heat pump according to a first embodiment of the present invention,
2 is a view showing a seawater purification tank of a cooling/heating switching system using a seawater heat heat pump according to a second embodiment of the present invention,
3 is a partial perspective cross-sectional view of the dissolved oxygen amount raising unit of FIG. 2,
4 is a perspective view showing a dissolution inducing member of a dissolved oxygen amount raising unit according to a third embodiment of the present invention
5 is a partial perspective cross-sectional view of a dissolved oxygen amount raising unit according to a fourth embodiment of the present invention,
6 is a partial perspective cross-sectional view of a dissolved oxygen amount raising unit according to a fifth embodiment of the present invention.

Hereinafter, a cooling/heating switching system using a heat pump according to a preferred embodiment of the present invention will be described in detail.

1 shows a cooling/heating switching system 5 using a heat pump according to a first embodiment of the present invention.

The cooling/heating switching system 5 using a heat pump according to the first embodiment of the present invention increases the water temperature of seawater supplied to store fish and waste in the water tank, which is the facility 10, depending on the season or external temperature, or For example, it is supplied by descending.

The facility 10 is not limited to a tank that stores seawater, may be a tank that stores fresh water, and a facility house (not shown) for cultivating crops may be applied.

A cooling/heating switching system 5 using a heat pump according to a first embodiment of the present invention includes a water storage tank 20 in which water for supplying to the facility 10 is stored; A heat pump unit 40 connected to the water storage tank 20 to increase or decrease the temperature of the water stored in the water storage tank 20 according to the circulation direction of the refrigerant exchanged with seawater; A water circulation unit 70 is provided for supplying the water raised or lowered by the heat pump unit 4 to the facility 10 or circulating the water of the facility 10 to the heat pump unit 40.

Since the cooling/heating switching system 5 using the heat pump according to the first embodiment of the present invention is applied to a water tank in which seawater is stored, seawater is stored in the water storage tank 20, and the seawater is purified and the amount of dissolved oxygen. It is preferable to further include a seawater purification unit 30 for supplying seawater to the water storage tank 20 after maintaining or rising.

First, the seawater purification unit 30 extends from the sea to the second seawater suction pipe 31 through which seawater is sucked, and the second seawater suction pipe 31 for a predetermined time so that foreign matter introduced together with the seawater is deposited downward. The upper part of the seawater purification tank 33 so that the seawater from which seawater introduced from the seawater intake pipe 31 is stored is stored, and the seawater from which foreign substances have been removed from the seawater purification tank 33 is supplied to the water storage tank 20 A second seawater discharge pipe 35 extending from the water storage tank 20 is provided.

The second seawater suction pipe 31 extends to the middle layer of the sea with a temperature of about 10°C, and a second seawater suction pump 34 for sucking seawater is installed on one side, and a filter that prevents foreign matter from entering when seawater is introduced at the end. (32) is equipped.

The second seawater discharge pipe 35 extends to the top of the seawater storage tank 33 so that the supernatant water from the seawater storage tank 33 can be discharged, and a third seawater suction pump for moving seawater to the water storage tank at one side ( 36) may be installed and a decanter (not shown) may be installed at an end extending into the seawater storage tank 33.

The cooling/heating switching system 5 using a heat pump according to the present invention is branched from the second seawater suction pipe 31 so that seawater can be directly supplied to the water tank from the second seawater suction pipe 31 without passing through the seawater purification unit. A first direct water supply pipe 39 extended to may be further provided.

The seawater purification tank 33 stores seawater introduced through the second seawater intake pipe 31, and is preferably stored for a predetermined time so that the foreign matter introduced together with the seawater can sink. A foreign material discharge valve (not shown) capable of discharging the may be installed.

The water storage tank 20 stores seawater supplied from the second seawater discharge pipe 35, and a water circulation unit 70, which will be described later, extends in the inner upper and lower portions. Although not shown, the water storage tank 20 may be supplied with seawater from a second direct water supply pipe (not shown) branching from the second seawater intake pipe and extending into the water storage tank.

The heat pump unit 40 raises or lowers the water temperature of seawater stored in the water storage tank 20 using seawater separately supplied as a heat source, and includes a first heat exchange unit 41 and a second heat exchange unit 51, A first refrigerant circulation pipe 61 and a second refrigerant circulation pipe 65 are provided.

The first heat exchange unit 41 includes a first seawater suction pipe 42 for sucking seawater from the sea, a first chamber 44 for storing seawater flowing from the first seawater suction pipe 42, and a first chamber ( 44) and a first heat exchanger 46 for exchanging the refrigerant and the seawater, and a first seawater discharge pipe 47 for discharging the seawater that has been introduced into the first chamber 46 and exchanged with the refrigerant to the sea. .

The first seawater suction pipe 42 extends to the middle layer of the sea with a temperature of about 10°C, and a first seawater suction pump 44 for sucking seawater is installed on one side, and a filter preventing the inflow of foreign substances when seawater is introduced at the end. 43 is mounted.

The seawater introduced into the first chamber 45 is heat-exchanged with the first heat exchanger 46, and then the first seawater discharge pipe by the transfer pressure of the first seawater suction pump 44 mounted on the first seawater suction pipe 42. It is discharged to the sea through (47). Unlike shown, a seawater discharge pump (not shown) for discharging seawater in the first chamber to the sea may be installed in the first seawater discharge pipe 47.

The second heat exchange unit 51 includes a second chamber 55 through which water flows from the water storage tank 20, and a second heat exchanger (which is located in the second chamber 55 and exchanges water flowing into the chamber). 56), the first and second water transfer pipes 52 and 54 extending to the second chamber to suck or discharge water in the water storage tank 20, and heat exchange with the refrigerant in the second chamber 55 The water is discharged to the water storage tank 20 or facility 10, or from the water storage tank 20 to the second chamber 55 to suck the water in the water storage tank 20 into the second chamber 55. It includes first and second water transfer main pipes 52 and 54 each extending and connected to the water circulation unit 70 to be described later.

The first water transfer main pipe 52 extends to the lower portion of the water storage tank 20 so as to suck or supply the seawater lowered by the temperature difference among seawater stored in the water storage tank 20.

The second water transfer main pipe 54 extends to the top of the water storage tank 20 so as to suck or supply the seawater raised to the room due to a temperature difference among seawater stored in the water storage tank.

The first refrigerant circulation pipe 61 connects each side of the first heat exchange part 41 and the second heat exchange part 51 and an expansion valve 64 for controlling the flow of refrigerant is installed. The second refrigerant circulation pipe 65 connects the other side of the first heat exchange part 41 and the second heat exchange part 51, and a compressor 66 and a four-way valve 67 are installed at one side.

Accordingly, the first and second heat exchange units 41 and 51 are connected to form a closed circuit through which the refrigerant is circulated by the first and second refrigerant circulation pipes.

The circulation unit 70 includes a supply pipe 73 and a return pipe 74 connected to the first and second water transfer main pipes 52 and 54, respectively;

A first bypass pipe 77 connecting the return pipe 74 connected to the first water transfer main pipe 52 and the second water transfer main pipe 54; A second bypass pipe 78 connecting the supply pipe 73 connected to the second water transport main pipe 54 and the first water transport main pipe 52; The supply pipe 73, the return pipe 74, and the first and second bypass pipes 78 are provided with valves V1-V4 for controlling the flow of seawater in the water tank.

A seawater circulation pump 76 for circulating seawater in the water storage tank 20 is installed in the supply pipe 73 or the return pipe 74.

In addition, a temperature sensor (not shown) for sensing the temperature inside the water storage tank may be installed in the water storage tank 20, and a temperature sensor for measuring the temperature of seawater may be installed in the water tank 10. .

The operation of the cooling/heating switching system using the seawater heat heat pump according to the present invention configured as described above will be described as follows.

First, the second heat exchanger 56 is used as an evaporator and the second heat exchanger 46 is used as a condenser by using the four-way valve of the heat pump unit 40 in order to supply seawater with a lowered temperature to the water tank. do.

In this state, the heat pump unit 40 is driven and the first seawater suction pump 44 and the seawater circulation pump 76 are driven.

The seawater in the water storage tank 20 circulates through the first and second water transfer main pipes 52 and 54 through the second chamber 55 to exchange heat with the second heat exchanger 56 to be cooled.

In addition, the seawater flowing into the first chamber 45 through the first seawater suction pipe 42 is exchanged with the first heat exchanger 46, thereby cooling the refrigerant passing through the first heat exchanger 46. .

The refrigerant circulation of the heat pump unit operated as described above constitutes a cycle in which the compressor → four-way valve → first heat exchanger → expansion valve → second heat exchanger → four-way valve → compressor.

Seawater in the water storage tank is lowered by the above-described action. Then, the seawater cooled in this way is supplied to the water tank through the supply pipe 73, and then the return pipe 74 is turned on and returned to maintain a constant water temperature lowered to the water tank.

In order to supply seawater with an elevated temperature to the water tank, the second heat exchanger 56 is used as a condenser and the second heat exchanger 46 is used as an evaporator using a four-way valve of the heat pump unit 40, Seawater in the second chamber 56 by recovering heat from the seawater flowing into the first chamber and supplying heat corresponding to the work amount of the compressor to the seawater flowing from the water storage tank 20 to the second chamber 56 Will heat up.

That is, by sensing the water temperature of seawater stored in the water tank and the water temperature of seawater stored in the water storage tank 20 by a temperature sensor installed in the water tank 10, their temperature drops below the set temperature, and the heat pump unit is driven. do.

The refrigerant circulation of the heat pump unit driven in this manner constitutes a cycle in which the compressor → four-way valve → second heat exchanger → expansion valve → first heat exchanger → four-way valve → compressor.

The heat pump unit 40 is driven and the first seawater suction pump 44 and the seawater circulation pump 76 are driven.

Seawater in the water storage tank 20 circulates through the first and second water transfer main pipes 52 and 54 through the second chamber 55 to heat exchange with the second heat exchanger 56 used as a condenser for heating. do. In addition, the seawater flowing into the first chamber 45 through the first seawater suction pipe 42 is exchanged with the first heat exchanger 46, so that the refrigerant passing through the first heat exchanger 46 is stored.

In this state, the heat pump unit 40 is driven and the first seawater suction pump 44 and the seawater circulation pump 76 are driven.

The seawater in the water storage tank 20 circulates through the first and second water transfer main pipes 52 and 54 through the second chamber 55 to exchange heat with the second heat exchanger 56 to be cooled.

In addition, the seawater flowing into the first chamber 45 through the first seawater suction pipe 42 is exchanged with the first heat exchanger 46, thereby cooling the refrigerant passing through the first heat exchanger 46. .

The refrigerant circulation of the heat pump unit operated as described above constitutes a cycle in which the compressor → four-way valve → first heat exchanger → expansion valve → second heat exchanger → four-way valve → compressor.

Seawater in the water storage tank is lowered by the above-described action. Then, the seawater cooled in this way is supplied to the water tank through the supply pipe 73, and then the return pipe 74 is turned on and returned to maintain a constant water temperature lowered to the water tank.

The cooling/heating switching system using the seawater heat heat pump according to the first embodiment of the present invention cools or heats facilities including a water tank by recovering heat from seawater, thereby facilitating facility management and reducing costs. In addition, the cooling/heating switching system using the seawater heat heat pump according to the first embodiment of the present invention has an advantage in that it is easy to control the temperature of the facility since cooling and heating can be easily switched according to the season or environment.

In addition, the cooling/heating switching system using the seawater heat heat pump according to the first embodiment of the present invention includes a seawater purification unit 30 when applied to seawater among facilities, so that foreign matter is filtered and dissolved in a tank in which seawater is stored. Since it can supply seawater with an increased oxygen content, there is an advantage of providing a comfortable environment for fish and shellfish to inhabit.

Meanwhile, in FIGS. 2 and 3, a cooling/heating switching system using a seawater heat heat pump according to a second embodiment of the present invention is shown. Components having the same function as in the drawings shown above are denoted by the same reference numerals.

The cooling/heating switching system using the seawater heat heat pump according to the second embodiment of the present invention increases the amount of dissolved oxygen in the structure of the cooling/heating switching system 5 using the seawater heat heat pump according to the first embodiment of the present invention. The unit 100 is further provided.

The seawater purification unit 30 further includes a dissolved oxygen amount raising unit 100 for increasing the amount of dissolved oxygen in seawater flowing into the seawater purification tank 33.

The dissolved oxygen amount raising unit 100 includes a seawater oxygen dissolution pipe 110, an oxygen supply pipe 120, and a plurality of dissolution inducing members 130.

The seawater oxygen dissolution pipe 110 extends vertically so that the end side of the second seawater intake pipe 31 extending in the vertical direction into the seawater purification tank 33 is accommodated therein, and has an inner diameter larger than the second seawater intake pipe 31. It has a hollow tube shape, and the lower part is submerged in seawater introduced into the seawater purification tank 33.

The oxygen supply pipe 120 is connected to the compressor to introduce external air into the seawater oxygen dissolution pipe 110. The oxygen supply pipe 120 is preferably formed through the lower side of the seawater oxygen dissolution pipe 110 so as to secure a wide area in which oxygen is stirred with seawater.

A plurality of dissolution inducing members 130 are installed in the seawater oxygen dissolution pipe 110 to irregularly change the movement path of seawater or generate friction so that oxygen is stirred into the seawater.

A plurality of dissolution inducing members 130 are installed to be arranged in the longitudinal direction of the sea oxygen dissolving tube 110 in the hollow of the sea oxygen dissolving tube 110 and formed through the sea water to pass through, but from the oxygen supply tube 120 when passing sea water It is formed through the supplied air and seawater in different positions and shapes to induce agitation.

Referring to FIG. 3, the plurality of dissolution inducing members 130 extend in one direction and extend in parallel with each other, and a plurality of first extension ribs 131 intersecting with the first extension ribs and extending in parallel with each other. Each of the second extension ribs 133 is formed in a mesh shape in which a plurality of through holes are formed.

The dissolution inducing member 130 crosses the first extension rib 131 or the second extension rib 133 of the dissolution inducing member 130 adjacent to the first extension rib 131 or the second extension rib 133. It is preferable that each is installed in the seawater oxygen melting pipe 110.

The cooling/heating switching system using the seawater heat heat pump according to the second embodiment of the present invention can increase the amount of dissolved oxygen in seawater stored in the seawater storage tank 33 by the dissolved oxygen amount raising unit 100, and dissolve a number of The induction member 130 can increase the dissolution efficiency of oxygen in seawater, so that seawater with high dissolved oxygen content can be supplied to the tank 10 through the water storage tank 20 frame, creating an environment suitable for fish and shellfish in the tank. There is an easy advantage.

On the other hand, FIG. 4 shows a plurality of stirring members of a system for cooling and heating a seawater heat heat pump according to a third embodiment of the present invention.

The system for cooling and heating the seawater heat heat pump according to the third embodiment of the present invention is a system for cooling and heating the seawater heat heat pump according to the second embodiment of the present invention except for a plurality of melting induction members 230 and 240. It is the same as the structure of

The plurality of dissolution inducing members 230 and 240 according to the third embodiment of the present invention include a first dissolution inducing member 230 and a second dissolution inducing member 240.

The first melting induction member 230 is formed in the shape of a disk having a first seawater through hole 231 penetrating therethrough so that the separation distance of the inner circumferential surface with respect to the outer circumferential surface repeatedly decreases and increases as the circumferential direction increases.

The second melting induction member 240 is installed at a position spaced apart from the first melting induction member 230 in the longitudinal direction of the seawater oxygen melting pipe 110, and is formed in a disk shape, with an outer diameter decreasing along the circumferential direction. The increase is repeatedly formed to form a plurality of second seawater through grooves 241 that are spaced apart from the inner circumferential surface of the seawater oxygen dissolving pipe 110 to pass seawater, and protrude in the seawater inflow direction on one surface of the seawater inflow direction. A plurality of auxiliary protrusions 243 are formed to induce dissolution of air in seawater.

In the cooling/heating switching system for the seawater heat heat pump according to the third embodiment of the present invention, the first melting induction member 230 and the second melting induction member 240 are alternately installed to secure a long movement path of seawater. Thus, oxygen dissolution efficiency can be increased.

Meanwhile, FIG. 5 shows a cooling/heating switching system using a seawater heat heat pump according to a fourth embodiment of the present invention. Components having the same function as in the drawings shown above are denoted by the same reference numerals.

The cooling/heating switching system using the seawater heat heat pump according to the fourth embodiment of the present invention is a seawater heat heat pump according to the second embodiment of the present invention except for the oxygen supply pipe 320 of the dissolved oxygen amount raising unit 100. It is the same as the structure of the cooling/heating switching system using.

The dissolved oxygen amount raising unit 100 includes a seawater oxygen dissolution pipe 110, an oxygen supply pipe 320, and a plurality of dissolution inducing members 130.

The oxygen supply pipe 320 penetrates each center of the plurality of dissolution inducing members 130 so that a wide area in which the seawater and air discharged from the oxygen supply pipe are mixed within the seawater oxygen dissolution pipe 110 is secured. It extends in parallel in the longitudinal direction of the melting pipe 110 and is accommodated in the seawater oxygen melting pipe 110.

Each of the plurality of dissolution inducing members 130 has a through hole 135 formed at the center side so that the oxygen supply pipe 320 can be extended through.

In addition, the second seawater intake pipe 31 is formed to extend parallel to the oxygen supply pipe 320 between the inner circumferential surface of the seawater oxygen dissolution pipe 110 and the oxygen supply pipe 320 so as not to interfere with the oxygen supply pipe 320.

The oxygen supply pipe 320 has a plurality of air discharge holes 321 formed on the outer circumferential surface of the outer circumferential surface through which external air introduced to the inner side is discharged to the seawater oxygen dissolution pipe.

In the cooling/heating switching system using the seawater heat heat pump according to the fourth embodiment of the present invention, an oxygen supply pipe penetrates a plurality of dissolution inducing members and an air discharge hole is formed on the outer circumferential surface, thereby securing a region where seawater and stirring are performed. Oxygen dissolution efficiency in seawater can be further increased.

Meanwhile, FIG. 6 shows a cooling/heating switching system using a seawater heat heat pump according to a fifth embodiment of the present invention.

The cooling/heating switching system using the seawater heat heat pump according to the fifth embodiment of the present invention includes a cooling/heating switching system using the seawater heat heat pump according to the fourth embodiment of the present invention except for a plurality of dissolution inducing members. It is the same as the structure.

The dissolved oxygen amount raising unit 100 of the cooling/heating switching system using the seawater heat heat pump according to the fifth embodiment of the present invention includes a seawater oxygen dissolution pipe 110, an oxygen supply pipe 320, and first and second It includes a dissolution inducing member (230, 240).

The first and second dissolution inducing members 230 and 240 are alternately repeatedly installed in the seawater oxygen dissolution pipe 110, and the second dissolution inducing member 240 has a through-hole 245 so that the oxygen supply pipe 320 extends through the center. ) Is formed.

Until now, the cooling/heating switching system using the seawater heat heat pump according to the present invention recovers heat from seawater to cool or heat facilities including a water tank, so facility management is easy and cost can be reduced. In addition, the cooling/heating switching system using the seawater heat heat pump of the present invention has the advantage of easy facility temperature control since cooling and heating can be easily switched according to the season or environment. In addition, the cooling/heating switching system using the seawater heat heat pump of the present invention can provide a comfortable environment for fish and shellfish to inhabit because foreign substances are filtered and seawater with an increased amount of dissolved oxygen is supplied to the tank in which seawater is stored. There is an advantage.

The cooling/heating switching system using the seawater heat pump according to the present invention has been described with reference to the embodiment shown in the drawings, but this is only exemplary, and various modifications and variations therefrom are those of ordinary skill in the art. It will be appreciated that equivalent embodiments are possible. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

5: Cooling and heating switching system using seawater heat pump
10: facility 20: water storage tank
30: seawater purification unit 31: second seawater suction pipe
33: seawater purification tank 34: second seawater suction pump
35: second seawater discharge pipe 40: heat pump unit
41: first heat exchange unit 42: second seawater suction pipe
44: first chamber 46: first heat exchanger
47: first seawater discharge pipe 51: second heat exchanger
52: first water transfer main building 54: second water transfer main building
55: chamber 56: second heat exchanger
61: first refrigerant circulation pipe 64: expansion valve
65: second refrigerant circulation pipe 66: compressor
67: four-way valve 70: water circulation unit
73: supply pipe 74: return pipe
76: seawater circulation pump 77: first bypass pipe
78: second bypass pipe 100: dissolved oxygen increase unit
110: seawater oxygen melting pipe 120: oxygen supply pipe
130: dissolution inducing member

Claims (7)

A water storage tank for storing water for supply to facilities;
A heat pump unit connected to the water storage tank and configured to heat or cool the water stored in the water storage tank according to the circulation direction of the refrigerant exchanged with seawater;
And a water circulation unit supplying water heated or cooled by the heat pump unit to the facility or circulating the water of the facility to the heat pump unit,
The heat pump unit
A first seawater suction pipe for sucking seawater from the sea, a first chamber for storing seawater introduced from the first seawater suction pipe, and a first heat exchanger positioned in the first chamber to exchange heat between the refrigerant and the seawater, A first heat exchange unit including a first seawater discharge pipe flowing into the first chamber to discharge seawater heat-exchanged with the refrigerant to the sea;
A second chamber into which water flows from the water storage tank; a second heat exchanger located in the second chamber to exchange heat with the water introduced into the second chamber; and water heat-exchanged with the refrigerant in the second chamber A second heat exchange unit including first and second water transfer main pipes connected to the water circulation unit to discharge the water to the water storage tank or the facility or to suck water in the water storage tank to the second chamber;
A first refrigerant circulation pipe connecting each side of the first heat exchange part and the second heat exchange part, and a second refrigerant circulation pipe connecting each other side of the first heat exchange part and the second heat exchange part,
A second seawater intake pipe extending from the sea and inhaling seawater, and a seawater purification tank in which seawater introduced from the second seawater intake pipe is stored for a predetermined period of time so that foreign matter introduced together with seawater through the second seawater intake pipe is deposited downward; And a seawater purification unit including a second seawater discharge pipe extending from an upper portion of the seawater purification tank to the water storage tank so that seawater from which the foreign substances have been removed from the seawater purification tank is supplied to the water storage tank; and
The water stored in the water storage tank is seawater introduced from the seawater purification tank,
The seawater purification unit
Further comprising a dissolved oxygen amount raising unit for increasing the amount of dissolved oxygen in seawater flowing into the seawater purification tank,
The dissolved oxygen amount raising unit
The end side of the second seawater suction pipe extending in the vertical direction into the seawater purification tank is extended vertically so as to be accommodated therein, and a hollow having an inner diameter larger than that of the second seawater suction pipe is formed, and the lower portion is introduced into the seawater purification tank. A seawater oxygen dissolver submerged in seawater,
An oxygen supply pipe for introducing external air into the seawater oxygen dissolution pipe,
It is installed in the hollow of the seawater oxygen dissolving pipe to be arranged in the longitudinal direction of the seawater oxygen dissolving pipe, and is formed through the seawater to pass through, but when the seawater passes through, the supply pipe air and the seawater and agitation are induced from the oxygen supply pipe. And a plurality of dissolution inducing members formed through the shape,
The second seawater suction pipe is formed to extend parallel to the oxygen supply pipe between the inner circumferential surface of the seawater oxygen dissolving pipe and the oxygen supply pipe so as not to interfere with the oxygen supply pipe,
The plurality of solubility inducing members
A first melting induction member having a first seawater through hole penetrating therein so as to repeatedly decrease and increase the separation distance of the inner circumferential surface with respect to the outer circumferential surface toward the inner circumferential direction;
It is installed at a position spaced apart from the first dissolution inducing member in the longitudinal direction of the seawater oxygen dissolving pipe, and the outer diameter decreases and increases repeatedly along the circumferential direction, so that the seawater is separated from the inner circumferential surface of the seawater oxygen dissolution pipe. A second dissolution guide member having a plurality of second seawater through grooves through which the seawater is passed, and a plurality of auxiliary protrusions formed on one surface of the seawater inflow direction protruding in the seawater inflow direction to induce mixing of the seawater and air And,
The first dissolution induction member and the second dissolution induction member are alternately repeatedly installed to ensure a long movement path of seawater,
The oxygen supply pipe is
The seawater oxygen dissolving pipe penetrates each center of the first and second dissolution inducing members so that a region in which the seawater and the air discharged from the oxygen supply pipe are mixed can be secured in the longitudinal direction of the seawater oxygen dissolution pipe Using a seawater heat heat pump, characterized in that a plurality of air discharge holes are formed on the outer circumferential surface to be discharged to the seawater oxygen melting pipe by extending parallel to the seawater oxygen melting pipe and receiving the air flowing inward along the longitudinal direction on the outer circumferential surface. Cooling/heating switching system delete delete delete delete delete delete

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