KR101332568B1 - Heating and cooling method of withdrawing heat by simultaneous using fresh water and sea water - Google Patents

Abstract

The present invention relates to a cooling-and-heating method by a waste water heat recovery using seawater and fresh water at the same time. The present invention especially utilizes seawater and fresh water; and enables the reduction of production costs as cheap components can be utilized for a heat exchanger or a heat storage tank on the side using fresh water. [Reference numerals] (AA) Heat exchange V1: ON, V3: OFF, V4: ON, V7:ON;(BB) Back wash V1: OFF, V3: ON, V4: OFF, V7:OFF;(CC) Region ii;(DD) Region iii;(EE) Discharge;(FF) Region i

Description

Heating and cooling method of wastewater heat recovery using seawater and freshwater at the same time {Heating and cooling method of withdrawing heat by simultaneous using fresh water and sea water}

The present invention relates to a cooling and heating method by waste water heat recovery, and in particular, by using sea water and fresh water at the same time for heat recovery, inexpensive parts can be used in a heat exchanger or a heat storage tank in a portion using the fresh water, thereby reducing manufacturing costs. You can do it.

In general, the aquaculture and marine cultured marine products in terrestrial aquaculture tanks are sensitive to temperature, and water management is the biggest factor affecting fish production in aquaculture farms. There is a big problem in the growth of marine aquaculture organisms due to reduced activity and food intake of aquaculture seed fish (fish, shellfish, crustaceans, etc.)

As a solution to this problem, the temperature of seawater flowing into aquaculture farms using a boiler has been controlled to an appropriate temperature range for a long time, but it has become a big burden for the farm operations due to the rising energy cost.

Therefore, in order to solve this problem, many techniques for controlling the temperature of the aquaculture tanks using wastewater (discharged water) discharged from aquaculture farms as heat sources have been used. Has been used.

However, in the prior art as described above, since the use of seawater as wastewater requires a costly material so that parts such as a heat exchanger are not corroded to seawater, there is a problem in that manufacturing cost is high.

On the other hand, the technique for adjusting the temperature of the aquaculture tank using the waste water as described above as a heat source is well known and described in detail in the following prior patent document, and the detailed description and illustration thereof are omitted.

Japanese Laid-Open Patent No. 2003-214722 Japanese Laid-Open Patent No. 2003-130490 Japanese Laid-Open Patent No. 2005-295939 Korea Registered Patent No. 0800281 Korea Patent Registration No. 0670759 Korean Patent Registration No. 075905 Korean Unexamined Patent No. 2009-0105608 Korean Patent Registration No. 0941375 Korean Patent Registration No. 1005996

The present invention is to solve the above-described problems, using seawater and fresh water at the same time for heat recovery, the seawater that can be used in the heat exchanger or heat storage tank of the portion using the low-cost parts can reduce the manufacturing cost It is an object of the present invention to provide a cooling and heating method by heat recovery of wastewater using and simultaneously using fresh water.

The present invention for achieving the above object is discharged from the aquaculture tank (S) and discharged to the outside via the first heat exchanger (130) and the seawater storage unit 110 from the washing filter 120 After the heat exchange with the waste seawater (WH) in the first heat exchanger 130 and then into the aquaculture tank (S) and the washing seawater (CH) for controlling the temperature of the aquaculture tank (S) and And a heat pump (HP) and a second heat storage tank (160) for adjusting the temperature of the cleaning sea water (CH), wherein the fan (F) and the second heat storage tank (160) are installed in the aquaculture tank (S). ) And fresh water (FH) circulates between the heat pump (HP) and the second heat storage tank (160), respectively, and a part of the washing sea water (CH) via the first heat exchanger (130) After exchanging heat through the two heat storage tank 160, it is input to one side of the three-way valve (V8) and the remaining washing sea water (CH) is directly input to the other side of the three-way valve (V8). After the intermixing there is an aspect in heating and cooling method of the waste heat recovery method of using seawater and fresh water is added to form the water tank (S) at the same time.

At this time, when the temperature of the washing seawater CH passing through the washing filter 120 is within a predetermined range, the circulation of the waste seawater WH is stopped while circulating the heat pump HP and the second heat storage tank 160. After the circulation of fresh water FH is stopped, the washing seawater CH may be directly introduced into the culture water tank S through the three-way valve V8.

In addition, the fresh water (FH) for heating the culture tank (S) is circulated between the fan (F) through the first hot water valve (VH-1) of the second heat storage tank 160, the heat pump Circulating between the second heat storage tank 160 through HP and the second hot water valve VH-2,

The washing sea water CH is first heated by the first heat exchanger 130, and then a portion thereof is secondly heated in the second heat storage tank 160, and then introduced into one side of the three-way valve V8. And, the remainder may be added to the other side of the three-way valve (V8), mixed and then introduced into the culture tank (S).

In addition, the fresh water (FH) is circulated between the fan (F) through the first cold water valve (VC-1) of the second heat storage tank 160 to cool the culture tank (S), the heat Circulating between the second heat storage tank 160 through a pump (HP) and the second cold water valve (VC-2), a portion of the cleaning sea water (CH) is the primary in the first heat exchanger (130) After cooling, one portion is secondly cooled in the second heat storage tank 160 and then is introduced into one side of the three-way valve V8, and the other is introduced into and mixed with the other side of the three-way valve V8. It is also possible to feed into the aquaculture tank (S).

In addition, the first heat storage tank 170 and the second heat exchanger 180 is installed between the heat pump (HP) and the second heat storage tank 160, the fresh water (FH) is the fan (F) ) And between the first heat storage tank 170 and between the first heat storage tank 170 and the second heat exchanger 180 and

It is also possible to circulate between the heat pump HP and the first heat storage tank 170, respectively.

In addition, the fresh water (FH) is circulated through the fifth hot water valve (VH-5) between the first heat storage tank 170 and the second heat exchanger 180 for heating the culture tank (S), Circulating through the fourth hot water valve (VH-4) between the second heat storage tank 160 and the second heat exchanger 180, the third hot water valve between the first heat storage tank 170 and the fan (F) Circulates through VH-3 and circulates through the sixth hot water valve VH-6 between the heat pump HP and the first heat storage tank 170, while the washing sea water CH is After the first heating by the first heat exchanger 130, one portion is secondly heated while passing through the second heat storage tank 160, and then one side is input to one side of the three-way valve (V8), and the rest is 3 It is also possible to be introduced into the other side of the directional valve (V8), mixed and then introduced into the culture tank (S).

In addition, the fresh water (FH) for cooling the aquaculture tank (S) is circulated through the fifth cold water valve (VC-5) between the first heat storage tank 170 and the second heat exchanger 180, Circulating through the fourth cold water valve (VC-4) between the second heat storage tank 160 and the second heat exchanger 180, the third cold water valve between the first heat storage tank 170 and the fan (F). And circulating through (VC-3), respectively, between the heat pump (HP) and the first heat storage tank (170) through the sixth cold water valve (VC-6), while the washing sea water (CH) is After being first cooled by the first heat exchanger 130, a part is secondly cooled while passing through the second heat storage tank 160, and then is introduced into one side of the three-way valve V8, and the other part is the third. It is also possible to be introduced into the other side of the directional valve (V8), mixed and then introduced into the culture tank (S).

The wastewater filter 140 further includes a wastewater filter 140 disposed on one side of the culture water tank S to filter the wastewater from the culture water tank S, and the wastewater passing through the wastewater filter 140 is the first heat exchange. The waste water filter 140 may be backwashed by introducing the washing seawater CH, which is washed through the washing filter 120, into the wastewater filter 140.

In addition, the wastewater storage unit 150 for storing the seawater storage unit 110 for storing the seawater (S) washed by the cleaning filter 120 and the wastewater (W) washed by the wastewater filter 140 and And, connected to the seawater storage unit 110, and after being put into the heat exchanger 130 through the washing filter 120 and discharged to the washing seawater pipe (P-2) connected to the culture tank (S) and the waste water storage Waste seawater pipe (P-1) connected to the unit 150 and discharged after being introduced into the heat exchanger 130 through the wastewater filter 140 and discharged to the outside, the cleaning filter 120 and the heat exchanger 130 Backwashing pipe (P3) branched from the washing seawater pipe (P-2) between the and connected to the wastewater filter 140, and one side from the heat exchanger 130 of the wastewater seawater pipe (P-1) to the outside It is connected to the discharge pipe and the other side includes a discharge pipe (P8) connected to the wastewater filter 140, the heat exchange during Close the three pipes (P3) and the discharge pipe (P8) to allow heat exchange through the waste sea water pipe (P-1) and the washing sea water pipe (P-2), and when washing, the backwash pipe (P3). It is also possible to open the discharge pipe (P8) to be discharged to the outside through the waste sea water pipe (P-1) after the washing sea water (CH) is introduced into the waste water filter (140).

In addition, the cleaning seawater pipe (P-2) is the first pipe (P1) disposed between the seawater storage unit 110 and the cleaning filter 120, and between the cleaning filter 120 and the heat exchanger (130). A second pipe P2 disposed in the backwashing pipe P3 and branched from one side, and a fourth pipe P4 exiting the heat exchanger 130 and introduced into the aquaculture tank S; Waste water pipe (P-1) is disposed between the seventh pipe (P7) disposed between the wastewater storage unit 150 and the wastewater filter 140, and is disposed between the wastewater filter 140 and the heat exchanger (130) It is also possible to include a sixth pipe (P6) that the backwash pipe (P3) joins, and a fifth pipe (P5) that is discharged from the heat exchanger (130) to the outside but the discharge pipe (P8) joins. .

In addition, the first valve (V1) installed in the seventh pipe (P7), the seventh pipe (P7), the sixth pipe (P6), the fifth pipe (P5) and the second pipe (P2) respectively. It is installed in the seventh pipe (P7) is disposed behind the flow direction than the first valve (V1), and in the sixth pipe (P6) is disposed behind the flow direction than the joining point of the backwash pipe (P3) In the fifth pipe (P5) is disposed in the flow direction ahead of the confluence point of the discharge pipe (P8), in the second pipe (P2) is installed in the flow direction behind the branch point of the backwash pipe (P3). And a fourth valve (V4), a third valve (V3) provided at each of the backwash pipe (P3) and a discharge pipe (P8), and a seventh valve (V7) provided at the fourth pipe (P4). Thus, during heat exchange, the backwashing pipe P3 and the discharge pipe are opened by opening the first valve V1, the fourth valve V4, and the seventh valve V7, and closing the third valve V3. Closed P8 The waste sea water pipe (P-1) and the washing sea water pipe (P-2) are opened to allow heat exchange, and during cleaning, the first valve (V1), the fourth valve (V4), and the seventh valve are used. After the V7 is closed and the third valve V3 is opened, the backwashing pipe P3 and the discharge pipe P8 are opened, and the washing seawater CH is introduced into the wastewater filter 140 and washed. It is also possible to discharge to the outside through the waste water pipe (P-1).

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

Prior to that, terms and words used in the present specification and claims should not be construed in a conventional and dictionary sense, and the inventor may properly define the concept of the term in order to best explain its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

According to the present invention as described above, inexpensive parts can be used in the heat exchanger or the heat storage tank of the portion using the fresh water by using sea water and fresh water simultaneously for heat recovery, thereby reducing the manufacturing cost.

1 is a conceptual diagram illustrating a heating method according to an embodiment of the present invention.
2 is a conceptual diagram illustrating a cooling method according to an embodiment of the present invention.
3 is a conceptual diagram illustrating a heating method according to another embodiment of the present invention.
4 is a conceptual view illustrating a cooling method according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The objectives, specific advantages and novel features of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. In the present specification, in adding reference numerals to the components of each drawing, it should be noted that the same components as much as possible, even if shown in different drawings. In addition, terms such as “first”, “second”, “one side” and “other side” are used to distinguish one component from another component, and a component is limited by the terms. no. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram illustrating a heating method according to an embodiment of the present invention, FIG. 2 is a conceptual diagram illustrating a cooling method according to an embodiment of the present invention, and FIG. 3 is a heating diagram according to another embodiment of the present invention. 4 is a conceptual diagram illustrating a cooling method according to another embodiment of the present invention.

The present invention is discharged from the aquaculture tank (S), as shown in Figure 1 and 2 and then discharged to the outside through the first heat exchanger (130) and out of the seawater storage unit 110 After washing the filter 120, the first heat exchanger 130 is heat exchanged with the waste seawater (WH) and then introduced into the aquaculture tank (S) to clean the seawater for controlling the temperature of the aquaculture tank (S) (CH), a heat pump (HP) and a second heat storage tank (160) for adjusting the temperature of the washing sea water (CH).

That is, the temperature of the washing seawater CH introduced into the aquaculture tank S is adjusted by heat exchange with the waste seawater WH, and the heat exchange is performed in the first heat exchanger 130 described above.

At this time, the fan (F) installed in the culture tank (S) to circulate between the second heat storage tank (160) fresh water (FH) for heat exchange with the internal air of the space where the culture tank (S) is collected. do.

In addition, the second heat storage tank 160 is also connected to the heat pump (HP) for additional heat exchange, and fresh water circulates between the second heat storage tank (160) and the heat pump (HP).

On the other hand, a part of the washing seawater (CH) via the first heat exchanger 130 is heat exchanged through the second heat storage tank 160 and then introduced to one side of the three-way valve (V8) and the remaining washing seawater ( CH) is directly added to the other side of the three-way valve (V8) and mixed with each other and then introduced into the culture tank (S).

That is, the secondary seawater temperature of the washing seawater CH, which is primarily heat exchanged by the wastewater seawater WH, is adjusted in the second heat storage tank 160, and the above-described fresh water FH is used as a heat source.

At this time, the second heat storage tank 160 is a second heat exchange of the washing seawater (CH) while the fresh water (FH) is independently circulated between the heat pump (HP) and the fan (F).

At this time, the washing sea water (CH) has two flow paths as described above. That is, a first flow path is directly injected into the three-way valve V8, and a second flow path is introduced into the three-way valve V8 after passing through the second heat storage tank 160.

That is, the washing seawater CH having passed through the first flow path is directly introduced into the three-way valve V8 via the first heat exchanger 130, and the washing seawater CH having passed through the second flow path is disposed at the first flow path. It is injected into the three-way valve V8 via the first heat exchanger 130 and the second heat storage tank 160.

The washing sea water CH having passed through these two paths is finally mixed in the three-way valve V8 and then introduced into the culture water tank S.

In the case of the present invention, the fan F, the heat pump HP, and the second heat storage tank 160 allow fresh water to circulate so that the heat pump HP or the second heat storage tank 160 is made of inexpensive material. To reduce manufacturing costs.

That is, in the past, there is a problem in that the manufacturing cost is increased by using an expensive material in order to prevent corrosion due to the use of sea water, but a low cost material can be used according to the present invention to reduce the manufacturing cost.

On the other hand, when the temperature of the washing seawater (CH) passing through the washing filter 120 is within a predetermined range, the circulation of the waste water (WH) is stopped while circulating the heat pump (HP) and the second heat storage tank (160). After the circulation of fresh water FH is stopped, the washing seawater CH may be introduced into the culture water tank S through the three-way valve V8.

That is, when the temperature of the washing seawater CH is at an appropriate temperature, it is not necessary to adjust the temperature through heat exchange, so that all of the washing seawater CH is directly fed to the culture tank S through the three-way valve V8. To be committed.

As shown in FIG. 1 for heating the aquaculture tank S, the fresh water FH is circulated between the fans F through the first hot water valve VH-1 of the second heat storage tank 160. The heat pump HP and the second hot water valve VH-2 are circulated between the second heat storage tank 160.

On the other hand, the cleaning sea water (CH) is first heated by the first heat exchanger 130 as described above, and then a portion of the second heat storage tank 160 is heated secondly and then the three-way valve ( V8) is injected into one side, and the rest is added to the other side of the three-way valve (V8), mixed and then introduced into the culture tank (S).

For example, in winter, since the temperature of the washing seawater CH is lower than the temperature of the waste seawater WH, the washing seawater CH is primarily heated by the first heat exchanger 130.

In addition, one portion of the first heated washing sea water (CH) is secondly heated in the second heat storage tank 160 as described above.

That is, the fresh water FH is heated using the heat amount from the fan F of the aquaculture tank S and the heat amount from the heat pump HP, and the heated fresh water FH is finally supplied to the second heat storage tank. The washing seawater CH is secondarily heated while passing through the second heat storage tank 160.

To this end, using the first hot water valve (VH-1) and the second hot water valve (VH-2) described above, each of the hot water valve is a configuration widely used in the heat storage tank or heat pump, so detailed description and illustration are omitted. do.

On the other hand, as shown in Figure 2 for cooling the culture tank (S), the fresh water (FH) is between the fan (F) through the first cold water valve (VC-1) of the second heat storage tank (160) While circulating at the same time, the second heat storage tank 160 is circulated through the heat pump HP and the second cold water valve VC-2.

At this time, one portion of the washing sea water (CH) is first cooled in the first heat exchanger 130 and then one portion is second cooled in the second heat storage tank (160) similar to the above described The directional valve (V8) is injected into one side, the rest is added to the other side of the three-way valve (V8) is mixed and then introduced into the culture tank (S).

For example, in summer, since the temperature of the washing seawater CH is higher than the temperature of the waste seawater WH, the washing seawater CH is first cooled by the first heat exchanger 130.

In addition, one portion of the primary cooled washing sea water CH is secondarily cooled in the second heat storage tank 160 as described above.

That is, the washing sea water CH exchanges heat with relatively low temperature fresh water FH coming from the fan F of the aquaculture tank S and relatively low temperature fresh water coming from the heat pump HP. Heat exchange with FH is performed in the second heat storage tank 160 to be secondarily cooled.

To this end, each of the hot water valves are widely used in heat storage tanks or heat pumps using the first cold water valve VC-1 and the second cold water valve VC-2. do.

That is, by using fresh water (FH) in the region I shown in FIGS. 1 and 2, a low-cost material can be used as described above, thereby reducing manufacturing costs.

On the other hand, as shown in Figure 3 and 4 also includes a first heat storage tank 170 and the second heat exchanger 180 is installed between the heat pump (HP) and the second heat storage tank (160). It is possible.

At this time, the fresh water (FH) is between the fan (F) and the first heat storage tank 170, between the first heat storage tank 170 and the second heat exchanger 180, and the heat pump (HP) and Circulated between the first heat storage tank 170, respectively.

That is, in the above-described configuration, the first heat storage tank 170 and the second heat exchanger 180 are added.

In this case, as shown in FIG. 3, the fresh water FH is heated through a fifth hot water valve VH-5 between the first heat storage tank 170 and the second heat exchanger 180. Circulate

In addition, the water is circulated through the fourth hot water valve VH-4 between the second heat storage tank 160 and the second heat exchanger 180.

In addition, a sixth hot water is circulated through the third hot water valve VH-3 between the first heat storage tank 170 and the fan F, and between the heat pump HP and the first heat storage tank 170. Each is circulated through the valves VH-6.

At this time, the washing sea water (CH) is first heated by the first heat exchanger 130 and then a portion is heated secondly while passing through the second heat storage tank 160 and then the three-way valve (V8) It is added to one side, the rest is added to the other side of the three-way valve (V8) is mixed and then introduced into the culture tank (S) as described above.

In this case, the second heat storage tank 160 receives heat from the second heat exchanger 180, and the second heat exchanger 180 primarily heats the heat via the first heat storage tank 170. The heat amount is supplied from the pump HP and the heat amount is secondarily supplied by the fan F.

The washing seawater CH is secondarily heated through the second heat storage tank 160, and is introduced into the culture water tank S as described above.

On the other hand, since fresh water (FH) is used in the region I shown in FIG. 3, the manufacturing cost can be reduced as described above.

On the other hand, to cool the culture tank (S), as shown in Figure 4 the fresh water (FH) is a fifth cold water valve (VC-5) between the first heat storage tank 170 and the second heat exchanger (180). Cycle through).

In addition, the fresh water FH circulates through the fourth cold water valve VC-4 between the second heat storage tank 160 and the second heat exchanger 180, and the first heat storage tank 170 and the fan ( F) circulates through the third cold water valve (VC-3).

In addition, fresh water FH circulates through the sixth cold water valve VC-6 between the heat pump HP and the first heat storage tank 170.

In this case, the washing sea water CH is first cooled by the first heat exchanger 130, and then a part of the washing sea water CH is secondly cooled while passing through the second heat storage tank 160, and then the three-way valve V8. One side is added, and the other is added to the other side of the three-way valve (V8) is mixed and then introduced into the culture tank (S).

That is, in the summer, the washing seawater CH introduced into the aquaculture tank S is first cooled in the first heat exchanger 130 and then secondly cooled by the second heat storage tank 160 as described above. do.

In this case, the second heat storage tank 160 is cooled by the second heat exchanger 180, and the second heat exchanger 180 primarily heats the heat pump through the first heat storage tank 170. It is cooled by (HP) and secondaryly cooled by heat exchange with the fan (F).

That is, in the region I illustrated in FIG. 4, fresh water FH may be used to reduce manufacturing costs as described above.

On the other hand, as shown in Figures 1 to 4 through the heat exchange between the waste sea water (WH) discharged from the aquaculture tank (S) and the washing sea water (CH) introduced into the aquaculture tank (S) ( While controlling the temperature of S), it is also possible to backwash the wastewater filter 140 for filtering the wastewater WH using the washing seawater CH.

That is, as described above, the washing seawater CH is heat exchanged with the waste seawater WH to control the temperature of the culture water tank S, and the wastewater filter 140 is reversed using the washing seawater CH. To wash.

Conventionally, as described above, there is a problem in that process efficiency is lowered by using only the purpose of simply backwashing the washing water produced by inputting energy.

The present invention has solved this problem, and the washing sea water (CH) for controlling the temperature of the culture water tank (S) after the heat exchange with the waste sea water (WH) and put into the culture water tank (S) and at the same time the cleaning Backwashing the wastewater filter 140 using seawater (CH).

In other words, by using the cleaning sea water (CH) at the same time for heat exchange and back-washing applications to be able to use the pre-produced cleaning sea water (CH) to increase the process efficiency.

To this end, the washing seawater (CH) introduced into the culture water tank (S) through the washing filter 120, and discharged from the culture water tank (S), and then heat exchanged with the washing seawater (CH) via the waste water filter (140) And a first heat exchanger (130) installed between the waste sea water (WH) and the waste sea water (WH) and the washing sea water (CH).

That is, the seawater is washed seawater (CH) through the washing filter 120 is introduced into the culture tank (S).

Meanwhile, the waste sea water (WH) discharged from the aquaculture tank (S) is introduced into the first heat exchanger (130) via the waste water filter (140) and heat exchanged with the washing sea water (CH).

At this time, the washing seawater (CH) washed through the washing filter 120 is introduced into the wastewater filter 140 to backwash the wastewater filter 140.

In addition, as shown, the seawater storage unit 110 for storing the seawater (S) washed by the cleaning filter 120 and the wastewater storage unit for storing the wastewater (W) washed by the wastewater filter 140 And 150.

At this time, the seawater storage unit 110 is connected to the first heat exchanger 130 through the washing filter 120, and then discharged to clean the seawater pipe (P-2) and connected to the culture tank (S), Waste seawater pipe (P-1) connected to the wastewater storage unit 150 is discharged after being input to the heat exchanger 130 through the wastewater filter 140 and discharged to the outside, and the cleaning filter 120 and the first Backwashing pipe (P3) branched from the washing seawater pipe (P-2) between the first heat exchanger 130 and connected to the wastewater filter (140), and one side of the wastewater pipe (P-1) of the first heat exchange Connected to a pipe discharged from the outside 130 and the other side includes a discharge pipe (P8) connected to the wastewater filter (140).

That is, after the seawater stored in the seawater storage unit 120 through the washing seawater pipe P-2 becomes the washing seawater CH through the washing filter 120, the first heat exchanger 130. After adjusting to a predetermined temperature through the aquaculture tank (S).

In addition, the waste sea water (W) stored in the waste water storage unit 150 through the waste sea water pipe (P-1) is introduced into the first heat exchanger 130 through the waste water filter 140 to clean the seawater. It is discharged to outside after adjusting the temperature of (CH).

In such a configuration, during heat exchange, the backwashing pipe P3 and the discharge pipe P8 are closed to mutually exchange heat through the waste sea water pipe P-1 and the washing sea water pipe P-2. do.

That is, as described above, the washing sea water CH is allowed to flow through the washing sea water pipe P-2, and the waste sea water WH is allowed to flow through the waste sea water pipe P-1 to mutually exchange heat. do.

In particular, during washing, the backwashing pipe (P3) and the discharge pipe (P8) are opened so that the washing seawater (CH) is introduced into the wastewater filter (140), washed, and then the outside through the wastewater water pipe (P-1). To be discharged.

On the other hand, the washing seawater pipe (P-2) is the first pipe (P1) disposed between the seawater storage unit 110 and the cleaning filter 120, the cleaning filter 120 and the first heat exchanger 130 The second back pipe (P2) is arranged between the backwashing pipe (P3) branched from one side, and the fourth pipe (P4) is introduced from the first heat exchanger 130 to the culture tank (S) Include.

In addition, the waste sea water pipe (P-1) is the seventh pipe (P7) disposed between the waste water storage unit 150 and the waste water filter 140, the waste water filter 140 and the first heat exchanger (130). The sixth pipe (P6) is disposed between the back washing pipe (P3) and the fifth pipe (P5) is discharged to the outside from the first heat exchanger 130, the discharge pipe (P8) joins. ).

With this configuration, the washing sea water CH can be used for backwashing or heat exchange as described above. At this time, the wastewater filter 140 can be backwashed during the heat exchange, and the heat exchange is stopped and the wastewater filter ( It is also possible to backwash the 1400.

To this end, the first valve V1 installed in the seventh pipe P7, the seventh pipe P7, the sixth pipe P6, the fifth pipe P5, and the second pipe P2, respectively. It is installed in the seventh pipe (P7) is disposed behind the flow direction than the first valve (V1), and in the sixth pipe (P6) is disposed behind the flow direction than the joining point of the backwash pipe (P3) In the fifth pipe (P5) is disposed in the flow direction ahead of the confluence point of the discharge pipe (P8), in the second pipe (P2) is installed in the flow direction behind the branch point of the backwash pipe (P3). And a fourth valve (V4), a third valve (V3) provided at each of the backwash pipe (P3) and a discharge pipe (P8), and a seventh valve (V7) provided at the fourth pipe (P4). can do.

In such a configuration, the first valve V1, the fourth valve V4, and the seventh valve V7 are opened, and the third valve V3 is closed to close the backwash pipe P3 during heat exchange. The discharge pipe P8 may be closed, and the waste sea water pipe P-1 and the washing sea water pipe P-2 may be opened to allow heat exchange.

In addition, during backwashing, the backwashing pipe P3 and the discharge pipe are closed by closing the first valve V1, the fourth valve V4, and the seventh valve V7, and opening the third valve V3. Opening (P8) may be the washing sea water (CH) is introduced into the waste water filter 140, washed and discharged to the outside through the waste sea water pipe (P-1).

In other words, the backwash is performed while the heat exchange is stopped.

Meanwhile, the illustrated second valve V2 is installed between the seawater storage unit 110 and the cleaning filter 120 to maintain an open state at the time of heat exchange or backwashing.

In addition, although not shown, it may include a pump for flowing the waste water (WH) and the washing sea water (CH), and the detailed description and illustration are omitted since such a pump is a well-known configuration.

In addition, the first to seventh valves (V1 ~ V7) may include a control unit for fully automatic operation, such a control unit and the valve is a well known technique, detailed illustration and description will be omitted.

Although the present invention has been described in detail through specific examples, this is for explaining the present invention in detail, and the present invention is not limited thereto, and a person having ordinary skill in the art within the technical idea of the present invention. It is obvious that modifications and improvements are possible.

Simple modifications and variations of the present invention are all within the scope of the present invention, and the specific scope of protection of the present invention will be apparent from the appended claims.

110: seawater storage unit 120: washing filter
130: first heat exchanger 140: wastewater filter
150: wastewater storage unit 160: second heat storage tank
170: first heat storage tank 180: second heat exchanger
P-1: Waste Seawater Piping HP: Heat Pump
P-2: Cleaning Seawater Piping P3: Backwash Piping
P8: exhaust pipe F: fan

Claims (11)

Waste water (WH) discharged from the culture tank (S) and discharged to the outside via the first heat exchanger (130), and after passing through the washing filter 120 from the seawater storage unit 110, the first heat exchanger After the heat exchange with the waste sea water (WH) at 130, the washing sea water (CH) and the temperature of the washing sea water (CH) to be introduced into the culture tank (S) to adjust the temperature of the culture tank (S) Including a heat pump (HP) and the second heat storage tank 160 for adjusting,
Fresh water (FH) is circulated between the fan (F) and the second heat storage tank 160 and the heat pump (HP) and the second heat storage tank 160 installed in the culture tank (S), respectively,
A portion of the washing seawater (CH) passing through the first heat exchanger 130 is heat exchanged through the second heat storage tank 160, and then is introduced into one side of the three-way valve V8, and the remaining washing seawater (CH) The three-way valve (V8) is directly added to the other side is mixed with each other and then added to the aquaculture tank (S) characterized in that the cooling and heating method by waste water heat recovery of the method using the seawater and fresh water at the same time. The method of claim 1,
Fresh water circulating the heat pump HP and the second heat storage tank 160 while stopping the circulation of the waste water WH when the temperature of the washing sea water CH passing through the cleaning filter 120 is within a predetermined range. Waste water heat recovery using the seawater and fresh water at the same time, characterized in that the washing seawater (CH) is introduced directly into the aquaculture tank (S) through the three-way valve (V8) after the circulation of the (FH) is stopped. Heating and cooling method by The method of claim 1,
The fresh water (FH) is circulated between the fan (F) through the first hot water valve (VH-1) of the second heat storage tank 160, the heat pump (HP) for heating the culture tank (S) ) And the second heat storage tank 160 through the second hot water valve (VH-2),
The washing sea water CH is first heated by the first heat exchanger 130, and then a portion thereof is secondly heated in the second heat storage tank 160, and then introduced into one side of the three-way valve V8. And, the rest is input to the other side of the three-way valve (V8) and then mixed and introduced into the culture water tank (S) characterized in that the cooling and heating method by waste water heat recovery of the method using the seawater and fresh water at the same time. The method of claim 1,
The fresh water FH circulates between the fans F through the first cold water valve VC-1 of the second heat storage tank 160 to cool the culture tank S, while the heat pump Circulating between the second heat storage tank 160 through HP) and the second cold water valve VC-2,
One portion of the washing sea water CH is first cooled in the first heat exchanger 130, and then one portion is secondly cooled in the second heat storage tank 160, and then one side of the three-way valve V8. And the remainder is added to the other side of the three-way valve (V8), mixed and then introduced into the aquaculture tank (S), the heating and cooling method by the waste water heat recovery method using the seawater and fresh water at the same time . The method of claim 1,
Further comprising a first heat storage tank 170 and the second heat exchanger 180 is installed between the heat pump (HP) and the second heat storage tank 160,
The fresh water (FH) is between the fan (F) and the first heat storage tank 170,
Between the first heat storage tank 170 and the second heat exchanger 180 and
Method of cooling and heating by waste water heat recovery of using the sea water and fresh water at the same time, characterized in that circulated between the heat pump (HP) and the first heat storage tank (170). The method of claim 5,
The fresh water (FH) is circulated through the fifth hot water valve (VH-5) between the first heat storage tank 170 and the second heat exchanger 180 for heating the culture tank (S), the second Circulating through the fourth hot water valve (VH-4) between the heat storage tank 160 and the second heat exchanger 180, the third hot water valve (VH) between the first heat storage tank 170 and the fan (F). -3), and circulates through the sixth hot water valve VH-6 between the heat pump HP and the first heat storage tank 170, respectively.
The washing sea water CH is first heated by the first heat exchanger 130, and then a portion thereof is heated secondly while passing through the second heat storage tank 160, and then one side of the three-way valve V8. And the remainder is added to the other side of the three-way valve (V8), mixed and then introduced into the aquaculture tank (S), the heating and cooling method by the waste water heat recovery method using the seawater and fresh water at the same time . The method of claim 5,
The fresh water (FH) is circulated through the fifth cold water valve (VC-5) between the first heat storage tank 170 and the second heat exchanger 180 for cooling the culture tank (S), the second Circulating through the fourth cold water valve (VC-4) between the heat storage tank 160 and the second heat exchanger 180, the third cold water valve (VC) between the first heat storage tank 170 and the fan (F). -3), and circulates through the sixth cold water valve VC-6 between the heat pump HP and the first heat storage tank 170, respectively,
The washing sea water CH is first cooled by the first heat exchanger 130, and then a portion thereof is secondly cooled while passing through the second heat storage tank 160, and then one side of the three-way valve V8. And the remainder is added to the other side of the three-way valve (V8), mixed and then introduced into the aquaculture tank (S), the heating and cooling method by the waste water heat recovery method using the seawater and fresh water at the same time . The method of claim 1,
Further comprising a wastewater filter 140 disposed on one side of the culture water tank (S) to filter the wastewater from the culture water tank (S), the wastewater passing through the wastewater filter 140, the first heat exchanger ( 130),
The wastewater heat of the method of simultaneously using the seawater and fresh water, characterized in that the washing seawater (CH) washed through the washing filter 120 is introduced into the wastewater filter 140 to backwash the wastewater filter 140. Heating and cooling method by recovery. 9. The method of claim 8,
A wastewater storage unit 150 for storing the seawater storage unit 110 storing the seawater S washed by the washing filter 120 and the wastewater W cleaned by the wastewater filter 140;
Is connected to the seawater storage unit 110, the washing seawater pipe (P-2) and then discharged after being introduced into the heat exchanger 130 through the cleaning filter 120 and connected to the culture tank (S),
Waste seawater pipe (P-1) connected to the wastewater storage unit 150 is discharged after being input to the heat exchanger 130 through the wastewater filter 140 and discharged to the outside, and
A backwashing pipe (P3) branched from the cleaning seawater pipe (P-2) between the cleaning filter (120) and the heat exchanger (130) and connected to the wastewater filter (140);
One side is connected to the pipe discharged to the outside from the heat exchanger 130 of the waste water pipe (P-1) and the other side includes a discharge pipe (P8) connected to the waste water filter 140,
At the time of heat exchange, the backwashing pipe P3 and the discharge pipe P8 are closed to perform heat exchange through the waste sea water pipe P-1 and the washing sea water pipe P-2.
When washing, the backwashing pipe (P3) and the discharge pipe (P8) is opened so that the washing seawater (CH) is introduced into the wastewater filter (140) to be washed and then discharged to the outside through the wastewater pipe (P-1). Cooling and heating method by waste water heat recovery of the method using the sea water and fresh water at the same time, characterized in that. 10. The method of claim 9,
The cleaning seawater pipe P-2 is disposed between the first pipe P1 disposed between the seawater storage unit 110 and the cleaning filter 120, and between the cleaning filter 120 and the heat exchanger 130. But the back washing pipe (P3) includes a second pipe (P2) branched from one side, and the fourth pipe (P4) is discharged from the heat exchanger 130 and introduced into the culture tank (S),
The waste sea water pipe (P-1) is disposed between the seventh pipe (P7) disposed between the wastewater storage unit 150 and the wastewater filter 140, and between the wastewater filter 140 and the heat exchanger (130). The sixth pipe (P6) to be joined to the backwash pipe (P3) and is discharged to the outside from the heat exchanger 130, the discharge pipe (P8) is characterized in that it comprises a fifth pipe (P5). Heating and cooling method by wastewater heat recovery by using sea water and fresh water at the same time. delete

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