KR101972541B1 - Absorption refrigeration system with using centrifuge separator - Google Patents

Abstract

In the present invention, by separating a high concentration of absorbent concentrate and a low concentration of absorbent dilute solution using a centrifugal separator, a separate heat source for separating the absorbent is not required, and thus energy efficiency can be improved. In addition, the low concentration absorbent dilute solution separated in the centrifuge can be separated back into the refrigerant and the absorbent concentrate using a membrane separator. In addition, the centrifuge is composed of an outer drum and the inner drum, the inner drum is formed of a reverse osmosis membrane, there is an advantage that can be performed both centrifugal separation and reverse osmosis with one device.

Description

Absorption refrigeration system with using centrifuge separator}

The present invention relates to an absorption type cooling system using a centrifuge, and more particularly, to an absorption type cooling system using a centrifuge that can further improve efficiency by regenerating an absorbent using a centrifuge.

Generally, an absorption type refrigerator is a system for obtaining cooling heat by using various heat sources, including an absorber for absorbing a refrigerant by an absorbent, a regenerator for heating the absorbed refrigerant to regenerate the refrigerant, a condenser for condensing the refrigerant, and a refrigerant. And an evaporator to evaporate.

However, the conventional absorption chiller requires a large amount of mesophilic heat for regeneration of the moisture absorbent or the desiccant, and thus has a problem in that heat consumption is consumed and efficiency is lowered.

Therefore, in recent years, the interest and research on the hybrid absorption type cooling system using solar heat as the heat source of the absorption refrigerator has increased.

However, the conventional hybrid absorption type cooling system using solar heat does not receive solar heat at night, in rainy or cloudy weather, and there is a problem in that there is a limit in operating the absorption chiller.

Korea Patent Registration No. 10-0522650

An object of the present invention is to provide an absorption cooling system using a centrifugal separator that can further improve the efficiency.

An absorption type cooling system according to the present invention includes a pump for pumping a rare solution mixed with a first refrigerant and an absorbent from an absorber; The high pressure rare solution pumped from the pump is supplied, and the centrifugal force is separated into a low concentration absorbent rare solution and a high concentration absorbent concentrate, and the absorbent rare solution is discharged, and the absorbent concentrate is supplied to the absorber. Separator; The second refrigerant is heat-exchanged with the process water, and the second refrigerant is evaporated to generate a second refrigerant vapor and then supplied to the absorber, and the process water includes an evaporator for cooling to generate cooling water.

According to another aspect of the present invention, an absorption cooling system includes: a pump for pumping a rare solution mixed with a first refrigerant and an absorbent from an absorber; The high pressure rare solution pumped from the pump is supplied, and the centrifugal force is separated into a low concentration absorbent rare solution and a high concentration absorbent concentrate, and the absorbent rare solution is discharged, and the absorbent concentrate is supplied to the absorber. Separator; A membrane separator for supplying the absorbent rare solution discharged from the centrifuge, separating the absorbent rare solution into the first refrigerant and the concentrated absorbent concentrate using a separator, and supplying the absorbent concentrate to the absorber; ; The second refrigerant is heat-exchanged with the process water, and the second refrigerant is evaporated to generate a second refrigerant vapor and then supplied to the absorber, and the process water includes an evaporator for cooling to generate cooling water.

In the present invention, by separating a high concentration of absorbent concentrate and a low concentration of absorbent dilute solution using a centrifugal separator, a separate heat source for separating the absorbent is not required, and thus energy efficiency can be improved.

In addition, the low concentration absorbent dilute solution separated in the centrifuge can be separated back into the refrigerant and the absorbent concentrate using a membrane separator.

In addition, the centrifuge is composed of an outer drum and the inner drum, the inner drum is formed of a reverse osmosis membrane, there is an advantage that can be performed both centrifugal separation and reverse osmosis with one device.

1 is a view showing an absorption cooling system using a centrifuge according to a first embodiment of the present invention.
2 is a view showing an absorption cooling system using a centrifugal separator according to a second embodiment of the present invention.
3 is a view showing an absorption cooling system using a centrifugal separator according to a third embodiment of the present invention.
4 is a view showing an absorption cooling system using a centrifugal separator according to a fourth embodiment of the present invention.
5 is a view showing an absorption cooling system using a centrifugal separator according to a fifth embodiment of the present invention.
6 is a perspective view schematically showing the centrifugal separator shown in FIG. 5.
7 is a cross-sectional view of the centrifuge shown in FIG. 6.

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

1 is a view showing an absorption cooling system using a centrifuge according to a first embodiment of the present invention.

Referring to FIG. 1, an absorption type cooling system 10 according to a first embodiment of the present invention includes an absorber 11, a pump 12, a centrifuge 14, and an evaporator 16.

The first refrigerant and the second refrigerant of the absorption type cooling system 10 according to the first embodiment of the present invention will be described as an example, respectively. The first refrigerant and the second refrigerant are not continuously circulated inside the absorption cooling system 10, are continuously supplied fresh from the outside, and discharged again after being used.

The absorber 11 receives the second refrigerant vapor evaporated in the evaporator 16 and absorbs the refrigerant-absorbent mixture. The inside of the absorber 11 maintains a vacuum state. The vacuum state is below atmospheric pressure, preferably can be set in the range of 0.1kPa to 7kPa. In order to maintain the inside of the absorber 11 in a vacuum state, a separate vacuum pump 11a may be provided.

The pump 12 pumps the low pressure rare solution in which the first refrigerant and the absorbent from the absorber 11 are mixed, and supplies the high pressure rare solution to the centrifuge 14.

As the rare solution, a fluid having hygroscopic properties may be used, and for example, an aqueous lithium bromide solution, an aqueous lithium chloride solution, an aqueous zinc chloride solution, ethylene glycol, propylene glycol, di-propylene glycol, tri-propylene glycol, Ethanol, sodium hydroxide aqueous solution, potassium hydroxide aqueous solution, etc. can be used.

The absorber 11 and the pump 12 are connected to the low pressure solution solution passage 12a, and the pump 12 and the centrifuge 14 are connected to the high pressure solution solution passage 12b.

The centrifugal separator 14 is supplied with a high pressure rare solution pumped from the pump 12, and is separated into a low concentration absorbent rare solution and a high concentration absorbent concentrate by centrifugal force during rotation. The absorbent dilute solution separated in the centrifuge 14 is discharged to the outside, and the high concentration of the absorbent concentrate is supplied to the absorber 11. The inside of the centrifuge 14 may be divided into a high concentration region and a low concentration region by the centrifugal force during rotation.

One side of the centrifugal separator 14 is connected to a supply pipe 14a receiving the high pressure rare solution from the pump 12.

The high concentration region side of the centrifuge 14 is connected to the first discharge pipe 14b for discharging the high concentration absorbent concentrate separated from the centrifuge 14 to the absorber 11. On the low concentration region side of the centrifuge 14, a second discharge pipe 14c for discharging the low concentration absorbent dilute solution separated from the centrifuge 14 to the outside is connected.

The evaporator 16 heat-exchanges the second refrigerant supplied from the outside and the process water P supplied from the outside, and evaporates the second refrigerant to generate the second refrigerant vapor. The evaporator 16 receives a heat source from the process water and evaporates the second refrigerant. The interior of the evaporator 16 maintains a vacuum. The vacuum state is below atmospheric pressure, preferably can be set in the range of 0.1kPa to 7kPa. The second refrigerant vapor generated in the evaporator 16 is supplied to the absorber 11.

The second refrigerant is water, and water to which one or more agents of purified water or scale generation inhibitors, corrosion inhibitors, and surfactants are added may be used.

The evaporator 16 and the absorber 11 are connected to the refrigerant vapor supply passage 16a. Since water is used as the second refrigerant, water vapor is supplied to the absorber 11 through the refrigerant vapor supply passage 16a.

The evaporator 16 is connected to a second refrigerant supply passage 16b for supplying the second refrigerant from the outside.

The evaporator 16 is provided with a cooling water generation passage 17 for absorbing a heat source of the process water P to cool the process water to generate cooling water.

The absorber 11 is provided with an absorber cooling unit 19 for removing the heat of absorption generated when the refrigerant vapor and the absorbent are mixed.

The operation of the absorption type cooling system 10 according to the first embodiment of the present invention configured as described above is as follows.

The high pressure rare solution pumped from the pump 12 flows into the centrifuge 14.

As the centrifuge 14 rotates, a high concentration of absorbent concentrate and a low concentration of absorbent dilute solution are separated by centrifugal force.

The absorbent concentrate separated in the centrifuge 14 is discharged to the absorber 11 through the first discharge pipe 14b.

The absorbent dilute solution separated in the centrifuge 14 is discharged to the outside through the second discharge pipe 14c.

In addition, the evaporator 16 is supplied with the second refrigerant from the outside. Here, the second refrigerant may use water purified from time water. In addition, at least one of a scale generation inhibitor, a corrosion inhibitor, and a surfactant may be added to the second refrigerant.

Since the evaporator 16 receives a new second refrigerant from the outside without using the first refrigerant discharged from the centrifuge 14, the temperature or components of the first refrigerant discharged from the centrifuge 14 There is no restriction on.

In the absorption type cooling system 10 configured as described above, by separating the absorbent concentrate using the centrifugal separator 14, a separate heat source is not required, and thus energy efficiency may be improved.

2 is a view showing an absorption cooling system using a centrifugal separator according to a second embodiment of the present invention.

2, the absorption type cooling system 20 according to the second embodiment of the present invention, the membrane separator 22 for separating the absorbent dilute solution discharged from the centrifuge 24 into the first refrigerant and the absorbent concentrate solution Since it further comprises a different from the first embodiment and the rest of the configuration and operation is similar, will be described in detail with respect to the different configuration.

In the second embodiment of the present invention, for example, the first refrigerant and the second refrigerant are the same water, and for example, the first refrigerant and the second refrigerant are circulated without being newly supplied.

The centrifugal separator 24 is supplied with a high pressure rare solution pumped from the pump 12 and separated into a low concentration absorbent rare solution and a high concentration absorbent concentrate by centrifugal force during rotation. The absorbent diluent separated in the centrifuge (24) is discharged to the membrane separator (22), and the high concentration of absorbent concentrate is supplied to the absorber (11). The inside of the centrifuge 24 may be divided into a high concentration region and a low concentration region by centrifugal force during rotation.

One side of the centrifugal separator 24 is connected to a supply pipe 24a for receiving the high pressure rare solution from the pump 12.

The high concentration region side of the centrifuge 24 is connected to the first discharge pipe 24b for discharging the high concentration absorbent concentrate separated from the centrifuge 24 to the absorber 11. On the side of the low concentration region of the centrifuge 24, a second discharge pipe 24c for discharging the low concentration absorbent dilute solution separated from the centrifuge 24 to the membrane separator 22 is connected.

The membrane separator 22 separates the low concentration absorbent dilute solution introduced through the second discharge pipe 24c into the first refrigerant and the high concentration absorbent concentrate using a separator.

The separator uses a reverse osmosis membrane (23).

The inside of the membrane separator 22 is partitioned into two first and second spaces 23a and 23b by the reverse osmosis membrane 23.

The second discharge pipe 24c is connected to the first space 23a to receive the absorbent rare solution from the centrifuge 24.

In addition, a third discharge pipe 22b is connected to the first space 23a for discharging the high concentration of the absorbent concentrate separated from the membrane separator 22 to the absorber 11.

The third discharge pipe 22b is connected to the first discharge pipe 24b to discharge the absorbent concentrate solution separated from the membrane separator 22 to the first discharge pipe 24b. In the present embodiment, for example, the third discharge pipe 22b is connected to the first discharge pipe 24b. For example, the present invention is not limited thereto, and the third discharge pipe 22b is directly connected to the absorber 11. Of course it is possible.

A fourth discharge pipe 22a for discharging the separated first refrigerant to the evaporator 16 is connected to the second space 23b.

 The fourth discharge pipe 22a is a flow path connecting the membrane separator 22 and the evaporator 16. Thus, the first refrigerant separated from the membrane separator 22 is supplied to the evaporator 16.

Accordingly, in the absorption type cooling system 20 according to the second embodiment of the present invention, the first refrigerant separated in the membrane separator 22 is used as a second refrigerant that exchanges heat with process water in the evaporator 16. Form a closed cycle.

However, the present invention is not limited thereto, and the first refrigerant may be discharged to the outside, and the second refrigerant different from the first refrigerant may be supplied to the evaporator 16, and a second refrigerant different from the first refrigerant may be supplied. Of course, additional supply is also possible.

The operation of the absorption type cooling system 20 according to the second embodiment of the present invention configured as described above is as follows.

The high pressure rare solution pumped from the pump 12 flows into the centrifuge 24.

As the centrifuge 24 rotates, a high concentration of absorbent concentrate and a low concentration of absorbent dilute solution are separated by centrifugal force.

The absorbent concentrate separated in the centrifuge 24 is discharged to the absorber 11 through the first discharge pipe 24b.

The absorbent dilute solution separated in the centrifuge 24 is supplied to the membrane separator 22 through the second discharge tube 24c.

In the membrane separator 22, the absorbent dilute solution may be separated into the first refrigerant and the absorbent concentrate through the reverse osmosis membrane.

The first refrigerant separated from the membrane separator 22 is supplied to the evaporator 16 through the fourth discharge pipe 22a. That is, since pure water may be separated in the membrane separator 22, the separated water may be reused in the evaporator 16.

The absorbent concentrate separated in the membrane separator 22 is supplied to the absorber 11.

In the absorption type cooling system 20 according to the second embodiment of the present invention configured as described above, the first refrigerant and the absorbent concentrate are separated by using the centrifugal separator 24 and the membrane separator 22 together. When no separate heat source is required, energy efficiency may be improved.

3 is a view showing an absorption cooling system using a centrifugal separator according to a third embodiment of the present invention.

3, the absorption type cooling system 30 according to the third embodiment of the present invention, the membrane separator 32 for separating the absorbent dilute solution discharged from the centrifuge 34 into the first refrigerant and the absorbent concentrate solution It includes, but for supplying a separate cooling fluid to the membrane separator 32 to heat the cooling fluid and the absorbent dilute solution to cool the absorbent rare solution, the cooling for accommodating the first refrigerant Since the discharge of the fluid back to the outside is different from that of the second embodiment, and the rest of the configuration and operation are similar, the detailed description will be mainly focused on different configurations.

In the third embodiment of the present invention, the first refrigerant and the second refrigerant are each described as water. The first refrigerant and the second refrigerant will not be circulated in the absorption type cooling system 30, and will be described as being discharged to the outside after being newly supplied and used from the outside.

The membrane separator 32 separates the absorbent rare solution separated and discharged from the centrifugal separator 34 into the first refrigerant and the absorbent concentrate using a separator.

The separation membrane uses a reverse osmosis membrane 33.

The inside of the membrane separator 32 is partitioned into first and second spaces 33a and 33b by the reverse osmosis membrane 33.

The cooling fluid supply passage 32a and the cooling fluid discharge passage 32c are connected to the first space 33a. The second discharge pipe 24c and the third discharge pipe 32b are connected to the second space 33b.

The cooling fluid supply passage 32a is a cooling fluid C for cooling the absorbent dilute solution passing through the membrane separator 32 while receiving the first refrigerant separated from the reverse osmosis membrane 33. It is a flow path to supply.

The cooling fluid C is not limited by the concentration, and various fluids such as purified water, high concentration aqueous solution, and low concentration aqueous solution may be used. The cooling fluid (C) may also use the discharged water discharged from the water treatment module, such as seawater desalination plant.

The cooling fluid discharge flow path 32c is a flow path for discharging the cooling fluid containing the first refrigerant to the outside. The cooling fluid discharge passage 32c may be directly discharged to the outside, or may be discharged to a separate wastewater circulation device.

The third discharge pipe 32b is a flow path for supplying the absorbent concentrate separated from the reverse osmosis membrane 33 to the absorber 11. The absorbent concentrate supplied to the absorber 11 through the third discharge pipe 32b is injected into the absorber 11 through a nozzle.

The operation of the absorption type cooling system 30 according to the third embodiment of the present invention configured as described above is as follows.

The high pressure rare solution pumped from the pump 12 flows into the centrifuge 34.

As the centrifugal separator 34 rotates, the high concentration absorbent concentrate and the low concentration absorbent dilute solution are separated by centrifugal force.

The absorbent concentrate separated in the centrifuge 34 is discharged to the absorber 11 through the first discharge pipe 34b.

The absorbent dilute solution separated in the centrifuge 34 is supplied to the membrane separator 32 through the second discharge pipe 34c.

In the membrane separator 32, the absorbent diluent can be separated into the first refrigerant and the absorbent concentrate through a reverse osmosis membrane.

At this time, since the cooling fluid C is supplied to the membrane separator 32, the cooling fluid C serves to receive the first refrigerant separated from the reverse osmosis membrane 33. . In addition, since the cooling fluid C exchanges heat with the absorbent dilute solution in the reverse osmosis membrane 33, the temperature of the absorbent concentrate solution exiting the membrane separator 32 is lowered. Therefore, the absorber 11 may not be cooled separately.

In addition, the evaporator 16 receives the second refrigerant through the second refrigerant supply passage 16b from the outside. Here, the second refrigerant may use water purified from time water. In addition, at least one of a scale generation inhibitor, a corrosion inhibitor, and a surfactant may be added to the second refrigerant.

Since the evaporator 16 receives a new second refrigerant from the outside without using the first refrigerant discharged from the membrane separator 32, the temperature or component of the first refrigerant discharged from the membrane separator 32 is reduced. There is no restriction on.

In the absorption type cooling system 30 according to the third embodiment of the present invention configured as described above, the centrifugal separator 34 and the membrane separator 32 are used together to separate the first refrigerant and the absorbent concentrate. Since a separate heat source is not required, energy efficiency can be improved.

In addition, a separate cooling fluid C may be used to collect the separated first refrigerant while cooling the absorbent concentrate from the membrane separator 32.

4 is a view showing an absorption cooling system using a centrifugal separator according to a fourth embodiment of the present invention.

Referring to FIG. 4, the absorption type cooling system 40 according to the fourth embodiment of the present invention uses both the centrifuge 34 and the membrane separator 32, and further includes a water treatment module 46. Since it is different from the third embodiment and the rest of the configuration is similar, the same reference numerals are used for similar configurations, and the detailed description will be mainly focused on different configurations.

The purified water treatment module 46 purifies the wastewater and the seawater supplied from the outside, and supplies purified water as the second refrigerant of the evaporator 16. The water treatment module 46 may be a seawater desalination plant, a water filter facility, or the like. As the filter used in the water purification equipment, a carbon filter, a sediment filter, an ultra filter, a reverse osmosis membrane filter, and the like may be used.

In the present embodiment, the water treatment module 46 is described as an example of a seawater desalination plant. Hereinafter, it will be described that the second refrigerant is sea water.

The purified water treatment module 46 includes an external supply passage 46a for receiving water from the outside, a purified water supply passage 46b for supplying the purified water to the evaporator 16, and a purified water from the purified water treatment module 46. A discharge water discharge passage 46c for discharging the discharged water remaining after the treatment is connected.

The effluent treated and discharged from the purified water treatment module 46 may be supplied to the cooling fluid of the membrane separator 32.

The wastewater discharge passage 46c is a passage connecting the purified water treatment module 46 and the membrane separator 32. The wastewater discharge passage 46c is connected to the cooling fluid supply passage 32a of the membrane separator 32. The wastewater discharge passage 46c supplies at least a portion of the wastewater discharged from the purified water treatment module 46 to the cooling fluid of the membrane separator 32.

Therefore, there is an advantage that can utilize the discharge water discharged from the purified water treatment module 46. In addition, the membrane separator 32 has an advantage that the cooling fluid is not supplied from the outside.

In the fourth embodiment of the present invention, for example, the whole of the wastewater discharged from the purified water treatment module 46 is supplied to the membrane separator 32, but the present invention is not limited thereto. It is possible.

In the case where the purified water treatment module 46 is the seawater desalination plant, the water discharge is high salinity seawater. After the high salinity seawater is supplied to the membrane separator 32 and the first refrigerant separated from the membrane separator 32 is accommodated, the high salt seawater may be discharged into the low salt seawater.

Therefore, by utilizing the high salinity seawater subjected to the first desalination treatment in the purified water treatment module 46 as a cooling fluid of the membrane separator 32, the absorbent concentrate can be cooled and the first refrigerant is also used. Low-salt seawater mixed with phosphorus can be finally discharged.

In the present exemplary embodiment, the second refrigerant supplied to the evaporator 16 is all supplied from the purified water treatment module 46. For example, the second refrigerant supplied to the evaporator 16 is not limited thereto. Only some of them may be supplied from the water treatment module 46.

5 is a view showing an absorption cooling system using a centrifugal separator according to a fifth embodiment of the present invention. 6 is a perspective view schematically showing the centrifugal separator shown in FIG. 5. 7 is a cross-sectional view of the centrifuge shown in FIG. 6.

5 to 7, in the absorption type cooling system 100 according to the fifth embodiment of the present invention, the centrifuge 140 includes an external drum 141, an internal drum 142, a diaphragm 143, and a supply pipe. 140a, the first discharge pipe 140b and the second discharge pipe 140c, and the inner drum 142 is formed of a reverse osmosis membrane because it is different from the first embodiment, it will be described in detail with respect to different configurations do.

The outer drum 141 is formed in a cylindrical shape, and is formed so that the high-pressure ash pumped from the pump 12 flows in and is received. The external drum 141 may be formed of a metal material or a polymer material.

The inner drum 142 is installed inside the outer drum 141 and is formed in a cylindrical shape. The inner drum 142 is coaxially connected to the outer drum 141 and integrally rotates together with the outer drum 141. The inner drum 142 is disposed to be spaced apart from the inner circumferential surface of the outer drum 141 by a predetermined interval so that an accommodation space in which the high pressure rare solution is accommodated is formed between the outer drum 141.

The inner drum 142 is formed of a reverse osmosis membrane. Since only the first refrigerant may pass through the inner drum 142 of the low concentration absorbent dilute solution separated by the centrifugal force in the accommodation space and collected toward the inner drum 142, the interior of the inner drum 142 may be The first refrigerant can be separated.

The diaphragm 143 is formed to connect an inner circumferential surface of the outer drum 141 and an outer circumferential surface of the inner drum 142. The diaphragm 143 is formed long in the axial direction of the outer drum 141 and the inner drum 142. The diaphragm 143 may rotate while pushing the high pressure rare solution in the outer drum 141 while rotating together when the centrifuge 140 rotates. That is, the phenomenon that the rare solution inside the outer drum 141 does not rotate due to inertia can be prevented. In the present embodiment, one diaphragm 143 is provided as an example. However, the present invention is not limited thereto, and the diaphragm 143 may be provided in plural, and of course, the diaphragm 143 may be formed in various shapes as long as it can flow the high pressure rare solution.

The supply pipe 140a is connected to an upper side of the external drum 141 and is a flow path for receiving the high pressure rare solution from the pump 12. The supply pipe 140a is connected to the high pressure rare solution flow passage 12b.

The first discharge pipe 140b is connected to a lower side of the outer drum 141, and is a flow path for discharging the absorbent concentrate separated from the outer drum 141 without remaining through the reverse osmosis membrane. The first discharge pipe 140b is connected to the absorber 11.

The second discharge pipe 140c is connected to a lower side of the inner drum 142 and is a flow path for discharging water that is the first refrigerant separated into the inner drum 142.

The centrifuge 140 is connected to a driving unit (not shown) for rotating the centrifuge 140.

The operation of the absorption type cooling system 100 according to the fifth embodiment of the present invention configured as described above is as follows.

The high pressure rare solution pumped from the pump 12 flows into the centrifuge 140.

When the centrifugal separator 140 rotates, a high concentration of absorbent concentrate is collected into the inner wall of the outer drum 141 by centrifugal force in the high pressure rare solution, and a low concentration of absorbent rare solution is used in the inner drum 142. Gathers to the outer wall.

That is, the inner wall side of the outer drum 141 becomes high concentration, and the outer wall side of the inner drum 142 becomes low concentration.

The first refrigerant may pass through the reverse osmosis membrane in the low concentration absorbent dilute solution collected toward the inner drum 142, and the first refrigerant may be separated into the inner drum 142.

At this time, the internal pressure of the external drum 141 is set to a pressure of reverse osmosis pressure or more.

In addition, when the centrifuge 140 rotates, the diaphragm 143 may flow the rare solution while pushing the rare solution in the external drum 141. As the rare solution flows in the rotation direction, separation of the absorbent concentrate and the absorbent rare solution may be more smoothly performed.

As described above, the absorption type cooling system 100 according to the fifth embodiment of the present invention is primarily separated by a centrifugal force into a high concentration of absorbent concentrate and a low concentration of absorbent dilute solution by centrifugal force, and reverse osmosis. Since the first refrigerant may be secondarily separated again through the inner drum 142 formed as a separator, there is an advantage that the second refrigerant may be separated twice by one device. Therefore, the structure can be simplified and the efficiency can be improved.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

11: absorber 12: pump
14,24,34,140: Centrifuge 16: Evaporator
22,32: membrane separator 46: water treatment module
141: outer drum 142: inner drum
143: diaphragm

Claims (11)

A pump for pumping the rare solvent mixed with the first refrigerant and the absorbent from the absorber;
A centrifugal separator supplied with the high pressure rare solution pumped from the pump, and separated into a low concentration absorbent rare solution and a high concentration absorbent concentrate by centrifugal force, and the absorbent concentrate supplied to the absorber;
Heat-exchanging the second refrigerant with the process water, and evaporating the second refrigerant to generate a second refrigerant vapor and then supplying it to the absorber, wherein the process water includes an evaporator that cools to produce cooling water,
The centrifuge,
When the high pressure rare solution pumped from the pump flows in, the external drum separating the high concentration absorbent concentrate and the low concentration absorbent rare solution by centrifugal force;
It is provided on the inner peripheral surface of the outer drum spaced apart a predetermined interval to form an accommodating space for receiving the high pressure rare solution pumped from the pump between the outer drum, it is connected coaxially with the outer drum and integrally rotated An inner drum formed of a reverse osmosis membrane separating and separating only the first refrigerant from the low concentration absorbent diluent separated by the centrifugal force;
A diaphragm which connects the inner circumferential surface of the outer drum and the outer circumferential surface of the inner drum to push and rotate the high pressure rare solution in the outer drum while rotating when the centrifuge rotates;
A supply pipe connected to an upper portion of the external drum to receive the high pressure rare solution from the pump to the accommodation space;
A first discharge pipe connected to a lower portion of the outer drum and discharging the absorbent concentrate from the outer drum without passing through the inner drum;
And a second discharge pipe connected to a lower portion of the inner drum and discharging the first refrigerant separated through the inner drum. A pump for pumping the rare solvent mixed with the first refrigerant and the absorbent from the absorber;
The high pressure rare solution pumped from the pump is supplied, and the centrifugal force is separated into a low concentration absorbent rare solution and a high concentration absorbent concentrate, and the absorbent rare solution is discharged, and the absorbent concentrate is supplied to the absorber. Separator;
A membrane separator for supplying the absorbent rare solution discharged from the centrifuge, separating the absorbent rare solution into the first refrigerant and the concentrated absorbent concentrate using a separator, and supplying the absorbent concentrate to the absorber; ;
Heat-exchanging the second refrigerant with the process water, and evaporating the second refrigerant to generate a second refrigerant vapor and then supplying it to the absorber, wherein the process water includes an evaporator that cools to produce cooling water,
The separator is a reverse osmosis membrane,
The inside of the membrane separator is partitioned into a first space in which a cooling fluid is supplied by the reverse osmosis membrane, and a second space in which the absorbent rare solution is supplied from the centrifugal separator.
Cooling for supplying the cooling fluid to the first space, to receive the first refrigerant separated into the first space through the reverse osmosis membrane, and to cool the absorbent dilute solution passing through the membrane separator A fluid supply passage;
And a cooling fluid discharge passage connected to the first space for discharging the cooling fluid containing the first refrigerant to the outside. A pump for pumping the rare solvent mixed with the first refrigerant and the absorbent from the absorber;
The high pressure rare solution pumped from the pump is supplied, and the centrifugal force is separated into a low concentration absorbent rare solution and a high concentration absorbent concentrate, and the absorbent rare solution is discharged, and the absorbent concentrate is supplied to the absorber. Separator;
A membrane separator for supplying the absorbent rare solution discharged from the centrifuge, separating the absorbent rare solution into the first refrigerant and the concentrated absorbent concentrate using a separator, and supplying the absorbent concentrate to the absorber; ;
Heat-exchanging the second refrigerant with the process water, and evaporating the second refrigerant to generate a second refrigerant vapor and then supplying it to the absorber, wherein the process water includes an evaporator that cools to produce cooling water,
The centrifuge,
When the high pressure rare solution pumped from the pump flows in, the external drum separating the high concentration absorbent concentrate and the low concentration absorbent rare solution by centrifugal force;
It is provided on the inner peripheral surface of the outer drum spaced apart a predetermined interval to form an accommodating space for receiving the high pressure rare solution pumped from the pump between the outer drum, it is connected coaxially with the outer drum and integrally rotated An inner drum formed of a reverse osmosis membrane separating and separating only the first refrigerant from the low concentration absorbent diluent separated by the centrifugal force;
A diaphragm which connects the inner circumferential surface of the outer drum and the outer circumferential surface of the inner drum to push and rotate the high pressure rare solution in the outer drum while rotating when the centrifuge rotates;
A supply pipe connected to an upper portion of the external drum to receive the high pressure rare solution from the pump to the accommodation space;
A first discharge pipe connected to a lower portion of the outer drum and discharging the absorbent concentrate from the outer drum without passing through the inner drum;
A second discharge pipe connected to a lower portion of the inner drum and discharging the first refrigerant separated through the inner drum,
The separator is a reverse osmosis membrane,
The inside of the membrane separator is partitioned into a first space in which a cooling fluid is supplied by the reverse osmosis membrane, and a second space in which the absorbent rare solution is supplied from the centrifugal separator.
Cooling for supplying the cooling fluid to the first space, to receive the first refrigerant separated into the first space through the reverse osmosis membrane, and to cool the absorbent dilute solution passing through the membrane separator A fluid supply passage;
And a cooling fluid discharge passage connected to the first space for discharging the cooling fluid containing the first refrigerant to the outside. The method according to any one of claims 1 to 3,
The second refrigerant is water,
A purified water treatment module for treating wastewater or seawater with water;
Absorption cooling system using a centrifugal separator further comprises a purified water supply passage for supplying purified water treated in the purified water treatment module to the evaporator. The method according to claim 2,
The second refrigerant is water,
A purified water treatment module for treating wastewater or seawater with water;
A purified water supply passage for supplying purified water treated by the purified water treatment module to the evaporator;
Absorption cooling system using a centrifugal separator for the discharge water discharge passage for supplying the discharge water treated and discharged from the water treatment module to the cooling fluid supply passage. delete delete delete delete delete delete

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