KR102130336B1 - Absorption refrigeration system with reverse osmosis filter - Google Patents

Abstract

Disclosed is an absorption refrigeration device to which a reverse osmosis filter member is applied. The disclosed absorption type refrigeration device to which the reverse osmosis filter member is applied is capable of cooling and heating by a refrigerant that is moved while being phase changed inside the absorption type refrigeration device to which the reverse osmosis filter member is applied, and an absorbent that absorbs the phase change refrigerant. Applied to the absorption refrigeration apparatus, the refrigerant in a liquid state comprising a regeneration member, a condensation member, an evaporation member, an absorption member and a reverse osmosis filter member, and constituting the absorption liquid transferred from the absorption member to the reverse osmosis filter member When some of them are separated from the reverse osmosis filter member and moved to the evaporation member, the absorbent liquid in which some of the refrigerant in the liquid state constituting the absorbent liquid is separated is moved to the regeneration member, and the liquid constituting the absorbent liquid After a part of the refrigerant in the state is separated, only the thermal energy corresponding to the amount of the absorbent liquid transferred to the regeneration member is supplied to the regeneration member, thereby relatively increasing the performance coefficient defined as a ratio of efficiency to the supplied thermal energy There is an advantage.

Description

Absorption refrigeration system with reverse osmosis filter

The present invention relates to an absorption refrigeration device to which a reverse osmosis filter member is applied.

The refrigeration unit cools and heats the frozen object by using latent heat, which is hidden heat generated when the refrigerant changes, such as ammonia and freon, sequentially moving evaporators, compressors, condensers, and receivers. will be.

Absorption refrigeration unit removes the compressor in a general refrigeration cycle and applies an absorber in which the absorbent is contained to form a refrigeration cycle of a generator, a condenser, an evaporator, and an absorber, and uses the refrigeration cycle including the absorber to cool and heat a frozen object In other words, as water is used as a refrigerant, it is in the spotlight as an eco-friendly device.

What can be presented as an example of such an absorption refrigeration apparatus are those of the patent documents presented below.

However, in order to evaporate the refrigerant in the generator constituting the absorption type refrigeration device and change the phase to a vaporized refrigerant, thermal energy for combustion of electricity, gas, light oil, kerosene, etc. must still be supplied from the outside. There is a need for an invention that can increase the efficiency of the absorption refrigeration apparatus, but there are not many inventions that can increase the efficiency of such a refrigeration apparatus.

Registered Patent No. 10-0491476, Date of registration: 2005.05.17, Name of the invention: Fluid filtration device and absorption chiller and absorption chiller Registered Patent No. 10-1037311, Registration Date: 2011.05.20, Name of the invention: Heat exchanger-integrated absorption chiller

An object of the present invention is to provide an absorption type refrigeration unit to which a reverse osmosis filter member capable of relatively improving the efficiency of the absorption type refrigeration unit while relatively reducing heat energy supplied from the outside.

The absorption type refrigeration device to which the reverse osmosis filter member according to an aspect of the present invention is applied is applied to an absorption type refrigeration device that can be cooled and heated by a refrigerant moving therein and an absorbent absorbing the phase change refrigerant. As a regeneration member for transferring the heat energy supplied from the outside to the absorbent liquid mixed with the coolant and the absorbent in a liquid state to phase change the coolant in the liquid state to a vapor state; A condensing member connected to the regeneration member to condense the refrigerant in a vapor state moved from the regeneration member to phase change to the liquid state refrigerant; An evaporation member connected to the condensation member to evaporate the refrigerant in a liquid state moved from the condensation member to phase change to the refrigerant in a vapor state; The refrigerant in the vapor state is accommodated therein, and the refrigerant in the vapor state moved from the evaporation member is absorbed by the absorbent, so that the refrigerant in the vapor state is phase-changed into the refrigerant in the liquid state, and accordingly, the refrigerant in the liquid state. And an absorbent member in which an absorbent liquid in which the absorbent is mixed is formed; And a concentration of the absorbent liquid therein, which is connected between the absorbent member and the regeneration member, and separates the portion of the refrigerant in a liquid state from the absorbent liquid formed by the absorbent member. Relatively higher than the reverse osmosis filter member; includes, the absorbent liquid in the regeneration member is moved to the absorbent member, some of the refrigerant in the liquid state constituting the absorbent liquid is phase-changed to the refrigerant in the vapor state The refrigerant moved to the condensing member and phase-changed from the condensing member to a liquid state is moved to the evaporation member, and the refrigerant phase-changed from the evaporating member to a vapor state is moved to the absorbing member, and the liquid state at the absorbing member The refrigerant, which has been phase-changed to be mixed with the absorbent, is moved to the reverse osmosis filter member after the absorbent liquid is formed, and a part of the refrigerant in the liquid state constituting the absorbent liquid is separated from the reverse osmosis filter member and the evaporation member When moved to, the absorbent liquid in which some of the refrigerant in the liquid state constituting the absorbent liquid is separated is moved to the regeneration member, and the concentration of the absorbent liquid moved from the regeneration member to the absorbent member is the reverse osmosis filter member The concentration of the absorbent liquid, which is relatively high compared to the concentration of the absorbent liquid transferred from the absorbent member to the regenerated member, is the concentration of the absorbent liquid transferred from the absorbent member to the reverse osmosis filter member. Relatively high, and the amount of the liquid moved from the reverse osmosis filter element to the evaporation member among the refrigerants, and external heat energy supplied to the regeneration member to phase change from the regeneration member to the vaporized refrigerant. The amounts are inversely proportional to each other, and accordingly, as the amount of the refrigerant in the liquid state constituting the absorbing liquid of the reverse osmosis filter member being moved to the evaporation member is relatively large, the thermal energy supplied from the outside becomes relatively small. Can It is characterized by.

The absorption type refrigeration device to which the reverse osmosis filter member according to another aspect of the present invention is applied is applied to an absorption type refrigeration device that can be cooled and heated by a refrigerant moving therein and an absorbent absorbing the phase change refrigerant. As an evaporation member for evaporating the refrigerant in the liquid state to phase change to the refrigerant in the vapor state; The refrigerant in the vapor state is accommodated therein, and the refrigerant in the vapor state moved from the evaporation member is absorbed by the absorbent, so that the refrigerant in the vapor state is phase-changed into the refrigerant in the liquid state, and accordingly, the refrigerant in the liquid state And an absorbent member in which an absorbent liquid in which the absorbent is mixed is formed; And a reverse osmosis filter member that increases the concentration of the absorbent liquid therein relative to the concentration of the absorbent liquid moved from the absorbent member by separating a portion of the refrigerant in the liquid state from the absorbent liquid formed in the absorbent member. Some of the refrigerant in the liquid state constituting the absorbent liquid is separated from the reverse osmosis filter member and moved to the evaporation member, and the absorbent liquid in which some of the refrigerant in the liquid state constituting the absorbent liquid is separated is transferred to the absorbent member The concentration of the absorbent liquid that is moved and moved from the reverse osmosis filter member to the absorbent member is relatively high compared to the concentration of the absorbent liquid that is moved from the absorbent member to the reverse osmosis filter member.

According to the absorption type refrigeration device to which the reverse osmosis filter member is applied according to one aspect of the present invention, the absorption type refrigeration device to which the reverse osmosis filter member is applied is moved with a phase change inside the absorption type refrigeration device to which the reverse osmosis filter member is applied. , Applied to an absorption type refrigeration device capable of cooling and heating by an absorbent absorbing the phase-change refrigerant, comprising a regeneration member, a condensation member, an evaporation member, an absorption member, and a reverse osmosis filter member, wherein the absorption member is When a part of the refrigerant in the liquid state constituting the absorbent liquid moved to the reverse osmosis filter member is separated from the reverse osmosis filter member and moved to the evaporation member, a part of the refrigerant in the liquid state constituting the absorbent liquid is separated The absorbed liquid is transferred to the regeneration member, and only a portion of the refrigerant in the liquid state constituting the absorbent liquid is separated, so that only the thermal energy corresponding to the amount of the absorbent liquid transferred to the regeneration member is supplied to the regeneration member, There is an effect that it is possible to relatively increase the performance coefficient defined by the ratio of the efficiency to the supplied thermal energy.

1 is a configuration diagram showing a state of the absorption type refrigeration device to which the reverse osmosis filter member according to the first embodiment of the present invention is applied.
Figure 2 is a cross-sectional view of the reverse osmosis filter member constituting the absorption type refrigeration device is applied to the reverse osmosis filter member according to the first embodiment of the present invention.
Figure 3 is a block diagram showing the appearance of the absorption type refrigeration unit is applied to the reverse osmosis filter member according to the second embodiment of the present invention.
4 is a block diagram showing a state of the absorption type refrigeration device to which the reverse osmosis filter member according to the third embodiment of the present invention is applied.

Hereinafter, an absorption type refrigeration device to which a reverse osmosis filter member according to embodiments of the present invention is applied will be described with reference to the drawings.

1 is a configuration diagram showing a state of the absorption type refrigeration device to which the reverse osmosis filter member according to the first embodiment of the present invention is applied, and FIG. 2 is an absorption type refrigeration device to which the reverse osmosis filter member according to the first embodiment of the present invention is applied. It is a cross-sectional view of the reverse osmosis filter member constituting the.

1 and 2 together, the absorption refrigeration apparatus 100 to which the reverse osmosis filter member according to the present embodiment is applied is formed by a refrigerant moving therein while being phase-changed, and an absorbent absorbing the phase-changing refrigerant. Applied to the absorption refrigeration apparatus capable of cooling and heating, and includes a regeneration member 110, a condensation member 120, an evaporation member 130, an absorption member 140, and a reverse osmosis filter member 150. .

Although not shown in this embodiment, the absorption type refrigeration device 100 to which the reverse osmosis filter member is applied may further include a heat exchanger to improve cooling and heating efficiency.

Prior to the detailed description, the absorption refrigeration apparatus 100 to which the reverse osmosis filter member is applied according to this embodiment includes an absorption refrigeration machine to which a reverse osmosis filter member is applied, an absorption cold and hot water heater to which a reverse osmosis filter member is applied, and an absorption heat to which a reverse osmosis filter member is applied. It is defined as including all pumps.

The absorption type freezer to which the reverse osmosis filter member is applied is the most commonly absorption type freezer to which the reverse osmosis filter is applied, and the single-effect absorption type refrigerator to which the regeneration member and the heat exchanger are constituted one by one, the regeneration member and the It includes a double-effect absorption type refrigerator with a reverse osmosis filter member composed of two heat exchangers each.

The absorption type cold and hot water machine to which the reverse osmosis filter member is applied is a dual-effect absorption type refrigerator to which the reverse osmosis filter member is applied, and a heating device for heating is added to combine cooling and heating.

The absorption type pump applied with the reverse osmosis filter member is to cool and heat a factory after receiving heat from sewage, etc., and a type 1 absorption heat pump with a reverse osmosis filter member supplying hot water and reverse osmosis supplying steam. And a two-piece absorption heat pump to which a filter member is applied.

The refrigerant is a working fluid of a refrigeration cycle, and takes heat from an object at a low temperature to transfer heat to an object at a high temperature, and water (H ₂ O) or ammonia (NH ₃ ) may be given as an example.

The absorbent absorbs the refrigerant in a liquid state, and lithium bromide (LiBr) or water may be provided as an example.

The lithium bromide is composed of 7.99 parts by weight of lithium (Li) and 92.01 parts by weight of bromide (Br) based on 100 parts by weight, and generally has similar chemical properties to salt.

In this embodiment, the refrigerant is made of water, and the absorbent is made of lithium bromide and is presented and described as an example.

The regeneration member 110 transfers thermal energy supplied from the outside to the absorbent liquid in which the coolant in the liquid state and the absorbent are mixed to phase change the coolant in the liquid state into a vapor state.

In detail, when heat energy such as electricity or heat is supplied from outside to heat the absorbent liquid in the regeneration member 110, some of the refrigerant in the liquid state constituting the absorbent liquid is phase-changed to the refrigerant in the vapor state, The absorbent liquid in which some of the refrigerant in the liquid state constituting the absorbent liquid is phase-changed to the coolant in the vapor state is relatively compared to the absorbent liquid when it is moved from the reverse osmosis filter member 150 to the regeneration member 110. It is present in the regeneration member 110 in a high concentration state.

Here, the concentration refers to the ratio of the absorbent to the refrigerant in the liquid state.

Some of the refrigerant in the liquid state constituting the absorbent liquid moved to the regeneration member 110 is phase-changed to a vapor state and then moved to the condensation member 120, and some of the refrigerant in the liquid state constituting the absorbent liquid After the phase change to the refrigerant in the vapor state, the remaining absorbent liquid is moved to the absorbent member 140.

Reference numeral 111 is an absorbent liquid transfer pipe for moving the remaining absorbent liquid, which is partially changed to the coolant in a vapor state, in the liquid state constituting the absorbent liquid in the regeneration member 110 to the absorbent member 140.

The condensation member 120 is connected to the regeneration member 110 to condense the refrigerant in a vapor state moved from the regeneration member 110 to phase change to the refrigerant in a liquid state.

In detail, the condensation member 120 is supplied with cooling water from the outside, and the refrigerant in the vapor state inside the condensation member 120 is condensed while exchanging heat with the coolant to phase change to the refrigerant in the liquid state.

At this time, due to the heat exchange between the coolant and the refrigerant in the vapor state, the temperature of the coolant when moving from the condensation member 120 to the outside is relatively higher than when it is moved from the outside to the condensation member 120. .

For example, when the cooling water at 31°C from the outside is moved to the condensing member 120, the refrigerant in the vapor state in the condensation member 120 condenses by heat exchange with the cooling water, and is transferred to the refrigerant in a liquid state. The temperature of the cooling water that is phase-changed and moved from the condensation member 120 to the outside is relatively high compared to the temperature when it is moved from the outside to the condensation member 120 due to heat exchange with the refrigerant in the vapor state. Phosphorus becomes 36.5°C.

Reference numeral 10 is a cooling water-side moving tube in which the cooling water is moved to exchange heat with the refrigerant in a vapor state in the condensing member 120.

The cooling water-side moving tube is connected to a cooling tower installed outside, and the cooling water having a relatively high temperature compared to the temperature when it is moved from the outside to the condensation member 120 is restored to an initial temperature in the cooling tower.

For example, the cooling water moving from the cooling tower in the outside to the condensing member 120 is 31° C., and the temperature rises to 36.5° C. due to heat exchange with the refrigerant in the vapor state in the condensing member 120. , The temperature of the cooling water rises to 36.5 ℃ becomes 31 ℃ again while moving to the cooling tower.

The evaporation member 130 is connected to the condensation member 120 to evaporate the refrigerant in the liquid state moved from the condensation member 120 to phase change to the refrigerant in the vapor state.

The inside of the evaporation member 130 is made of a relatively low pressure compared to the outside. Then, the boiling point of the refrigerant in the liquid state is lowered, so that the refrigerant in the liquid state can be vaporized even at a relatively low temperature compared to the outside, that is, the liquid can be converted into a gas, and thus the refrigerant in the liquid state is external. In comparison, it is evaporated even at a relatively low temperature to phase change to the refrigerant in the vapor state.

For example, when the pressure inside the evaporation member 130 becomes a vacuum of 5 to 6.5 mmHg, the refrigerant in the liquid state is phase-changed to the refrigerant in the vapor state at 5°C.

In addition, the evaporation member 130 is supplied with cold water to heat exchange with the refrigerant in the liquid state inside the evaporation member 130 from outside, the cold water supplied from the outside to be moved to the evaporation member 130 from the outside The temperature when moving from the evaporation member 130 to the outside is relatively lower than the temperature at the time.

For example, when the cold water of 12°C supplied from the outside is moved to the evaporation member 130, the cold water is exchanged with the refrigerant in the liquid state inside the evaporation member 130, lowered to 7°C, and then evaporated The member 130 is moved outward.

Reference numeral 20 is a cold water-side moving tube through which the cold water is moved.

The cold water-side moving pipe may be connected to an air conditioner installed in a building or house to cool the inside of the building or house.

The absorbent member 140 accommodates the absorbent therein, and the refrigerant in the vapor state moved from the evaporation member 130 is absorbed by the absorbent, so that the refrigerant in the vapor phase changes to the refrigerant in the liquid state. Accordingly, an absorbent liquid in which the refrigerant in the liquid state and the absorbent are mixed is formed.

In this embodiment, the evaporation member 130 and the absorption member 140 are separated between the evaporation member 130 and the absorption member 140, but the refrigerant in the vapor state moves in the evaporation member 130. The partition wall 135 formed of a plurality of spaced through holes is installed so as to be possible.

Reference numeral 136 stores the refrigerant in the liquid state in the evaporation member 130 that is not evaporated but remains in the evaporation member 130, and the refrigerant and the absorption in the liquid state in the evaporation member 130. It is a heat exchange prevention wall separating the lower space of the evaporation member 130 and the lower space of the absorption member 140 so that heat exchange between the absorbent liquids present in the member 140 is prevented.

The initial pressure inside the evaporation member 130 is maintained at a pressure lower than the external pressure, for example, a pressure close to vacuum, and the evaporation member is changed while the refrigerant in the liquid phase changes to the refrigerant in the vapor state. When the internal pressure of 130 is relatively high, a pressure difference is generated between the pressure of the evaporating member 130 that is relatively high and the pressure inside the absorbing member 140, and accordingly, in the evaporating member 130 The refrigerant in the formed vapor state moves to the absorbing member 140 via the partition wall 135.

The absorbent absorbs the refrigerant in the vapor state, and when the refrigerant in the vapor state is absorbed, heat is generated, so that the refrigerant in the vapor phase changes to the refrigerant in the liquid state, wherein the refrigerant in the liquid state The absorbent is mixed to form the absorbent liquid.

In this embodiment, by presenting the refrigerant as water, the absorbent is presented as the lithium bromide capable of absorbing the water.

Due to the relatively high pressure inside the evaporation member 130, the refrigerant in the vapor state formed in the evaporation member 130 moves to the absorption member 140 and is phase-changed to the refrigerant in the liquid state, and the liquid state. When the refrigerant of the is absorbed by the absorbent in the absorbent member 140, the refrigerant in the vapor state existing inside the evaporating member 130 is relatively reduced, and accordingly the pressure inside the evaporating member 130 is Relatively low, it returns to the initial pressure.

The reverse osmosis filter member 150 is connected between the absorption member 140 and the regeneration member 110, and by separating a portion of the refrigerant in a liquid state from the absorption liquid formed by the absorption member 140, the The concentration of the absorbent liquid inside the reverse osmosis filter member 150 is increased relative to the concentration of the absorbent liquid moved from the absorbent member 140.

In detail, the reverse osmosis filter member 150 includes a filter body 151, a filter unit 152, an absorption-side moving tube 153, a refrigerant-side moving tube 154, and an absorption member-side connecting tube 155. , Evaporation member side connection pipe 156, a regeneration member side connection pipe 157, and a pressing portion 158.

The filter body 151 constitutes an outer frame of the reverse osmosis filter member 150, and components are installed therein.

In the filter unit 152, a plurality of filter body 151 are spaced apart at a predetermined interval therebetween to separate the absorbent liquid in which the absorbent and the liquid coolant are mixed into the liquid coolant and the absorbent. As such, a membrane filter or the like may be presented as an example.

Here, the membrane filter is a filter capable of separating substances of different properties by passing a substance to be separated through fine pores of 10 µm or less.

In this embodiment, when the absorbent liquid passes through the filter unit 152, it is separated into the refrigerant in the liquid state and the absorbent by pressure transmitted from the pressing unit 158, respectively.

The absorption-side moving tube 153 is positioned between the filter units 152 installed spaced apart at regular intervals, and the absorbent separated by the filter unit 152 among the absorption liquid is moved.

The refrigerant-side moving tube 154 is positioned between the filter parts 152 installed spaced apart at regular intervals, and is installed spaced apart from the absorption-side moving tube 153, separated by the filter part 152 among the absorption liquid. The refrigerant in the liquid state is moved.

The absorbing member-side connecting pipe 155 connects between the absorbing member 140 and the filter body 151, and the absorbing liquid formed in the absorbing member 140 through the absorbing member-side connecting pipe 155 The reverse osmosis filter member 150 is moved.

The evaporation member-side connecting pipe 156 connects the evaporation member 130 and the distal end of the refrigerant-side moving tube 154 in a direction in which the refrigerant in the liquid state moves, and the evaporation member-side connection tube 156 The refrigerant in the liquid state separated by the filter unit 152 is moved to the evaporation member 130.

The regeneration member side connection pipe 157 connects the regeneration member 110 to the distal end of the absorption side movement pipe 153 in the direction in which the absorbent is moved, and through the regeneration member side connection pipe 157 The absorbent separated by the filter unit 152 is moved to the regeneration member 110.

The pressure unit 158 supplies pressure to the filter body 151, and a pressure pump or the like may be provided as an example.

When the pressurizing portion 158 supplies pressure inside the filter body 151, the absorbent liquid passes through the filter portion 152 by the pressure of the pressurizing portion 158, and the refrigerant in the liquid state and the The refrigerant separated into an absorbent, and the refrigerant in the separated liquid state is moved to the evaporation member 130 through the evaporation member-side connector 156, and the separated absorbent is passed through the regeneration member-side connector 157. It is moved to the regeneration member 110.

Then, the amount of the refrigerant in the liquid state moved from the absorption member 140 to the regeneration member 110 is reduced compared to the conventional absorption refrigeration device, and accordingly the liquid state in the regeneration member 110 is reduced. Since the amount of the heat energy supplied from the outside to evaporate the refrigerant is relatively reduced, the efficiency of the absorption type refrigeration device 100 to which the reverse osmosis filter member is applied can be relatively increased.

Meanwhile, the amount of the thermal energy supplied from the outside to the regeneration member 110 is determined according to the amount of the refrigerant in a liquid state separated from the reverse osmosis filter member 150.

That is, the amount of the refrigerant moved to the evaporation member 130 among the refrigerants separated from the reverse osmosis filter member 150 and the regeneration member to be phase-changed from the regeneration member 110 to the refrigerant in the vapor state ( The amount of external thermal energy supplied to 110) is inversely proportional to each other, and accordingly, the amount of the refrigerant moving in the liquid state constituting the absorbent liquid of the reverse osmosis filter member 150 is relatively large. As it gets higher, the thermal energy supplied from the outside can be made relatively small.

As the absorption type refrigeration device 100 to which the reverse osmosis filter member is applied is configured as above, the absorbent liquid in the regeneration member 110 is moved to the absorbent member 140, and the liquid state constituting the absorbent liquid is Some of the refrigerant is phase-changed to the refrigerant in the vapor state to move to the condensing member 120, and the refrigerant phase-changed from the condensing member 120 to the liquid state is moved to the evaporation member 130, and the evaporation After the refrigerant phase-changed from the member 130 to a vapor state is moved to the absorption member 140, the refrigerant phase-changed from the absorption member 140 to a liquid state is mixed with the absorbent to form the absorbent liquid. When it is moved to the reverse osmosis filter member 150 and a part of the refrigerant in the liquid state constituting the absorption liquid is separated from the reverse osmosis filter member 150 and moved to the evaporation member 130, the absorption liquid is constituted. The absorbent liquid in which some of the refrigerants in the liquid state are separated is moved to the regeneration member 110.

On the other hand, the absorption member 140 constituting the absorption type refrigeration unit 100 to which the reverse osmosis filter member is applied, and the reverse osmosis filter member 150 and the regeneration member 110 have liquid refrigerant and the absorbent in the liquid state. The mixed absorbent liquid flows, but the concentration of the absorbent liquid varies depending on whether the refrigerant in the liquid state constituting the absorbent liquid is phase-changed or moved to other components.

That is, due to the phase change of the refrigerant in the liquid state constituting the absorption liquid, the concentration of the absorption liquid moved from the regeneration member 110 to the absorption member 140 is the regeneration in the reverse osmosis filter member 150 Relatively high compared to the concentration of the absorbent liquid moved to the member 110, and the refrigerant in the liquid state constituting the absorbent liquid is moved from the reverse osmosis filter member 150 to the evaporation member 130, the reverse The concentration of the absorbent liquid transferred from the osmotic filter member 150 to the regeneration member 110 is relatively higher than the concentration of the absorbent liquid transferred from the absorbent member 140 to the reverse osmosis filter member 150.

In the present embodiment, depending on the concentration of the absorbent liquid, the absorbent liquid moved from the regenerated member 110 to the absorbent member 140 is concentrated liquid and moved from the reverse osmosis filter member 150 to the regenerated member 110. The absorbent liquid is an intermediate liquid, and the absorbent liquid transferred from the absorbent member 140 to the reverse osmosis filter member 150 is defined as a rare liquid.

On the other hand, in this embodiment, the absorption member side valve 160 is connected between the evaporation member 130 and the absorption member 140.

When the refrigerant in the liquid state separated from the reverse osmosis filter member 150 is moved to the evaporation member 130, the absorption member side valve 160 may have the absorbent moved together with the refrigerant in the liquid state. In this case, the absorbent is moved from the evaporation member 130 to the absorption member 140.

In detail, when the absorbing member side valve 160 is closed, when the refrigerant in the liquid state separated from the reverse osmosis filter member 150 is moved to the evaporation member 130, the reverse osmosis filter member 150 is not The absorbent mixed with the refrigerant in a liquid state separated from the reverse osmosis filter member 150 in a separated state and moved to the evaporation member 130 is moved together and then laminated inside the evaporation member 130. .

On the other hand, when the absorbing member side valve 160 is opened, the absorbent stacked inside the evaporating member 130 is moved to the absorbing member 140 via the absorbing member side valve 160.

The opening and closing of the valve 160 on the absorption member side is controlled by a control unit (not shown) installed inside or outside the absorption refrigeration device 100 to which the reverse osmosis filter member is applied.

The control unit has a preset amount of the absorbent to control the opening and closing of the absorbent member side valve 160, and after comparing the amount of the absorbent stacked on the absorbent member 140 with the preset amount of the absorbent The opening and closing of the valve 160 on the absorbing member side is adjusted.

Hereinafter, the operation of the absorption type refrigeration device 100 to which the reverse osmosis filter member according to this embodiment is applied will be described with reference to the drawings.

Since the absorption type refrigeration device 100 to which the reverse osmosis filter member is applied is made of a circulation cycle, it is not possible to determine a start point and an end point, but in this embodiment, it will be described as starting from the regeneration member 110.

First, a portion of the refrigerant in the liquid state is phase-changed into the refrigerant in the vapor state by externally supplying the thermal energy to the absorption liquid in which the refrigerant in the liquid state accommodated in the regeneration member 110 and the absorbent are mixed.

Among the refrigerants in the liquid state, the refrigerant in a phase-changed vapor state is moved to the condensation member 120 connected to the regeneration member 110.

At this time, a portion of the refrigerant in the liquid state constituting the absorbent liquid is phase-changed to a vapor state, so that the concentration is relatively high, that is, the absorbent liquid in the concentrated liquid state is transferred to the absorbent member 140 through the absorbent liquid moving pipe 111. Is moved.

Then, the refrigerant in the vapor state moved from the regeneration member 110 to the condensation member 120 exchanges heat with the coolant supplied from the outside, and thus the refrigerant in the vapor state condenses to the liquid state. Phase change to refrigerant.

The refrigerant in the liquid phase changed from the condensation member 120 is moved to the evaporation member 130 connected to the condensation member 120.

Then, the refrigerant in the liquid state moved to the evaporation member 130 is phase-changed to the refrigerant in the vapor state.

At this time, the inside of the evaporation member 130 maintains a relatively low pressure in flight to external pressure, so that the refrigerant in the liquid state boils at a relatively low temperature compared to the external temperature.

In addition, the evaporation member 130 heat exchanges with the cold water supplied from the outside, and accordingly, the cold water is in a relatively low temperature state compared to the temperature when it is moved from the outside to the evaporation member 130. The evaporation member 130 is moved outward.

As the refrigerant in the liquid state in the evaporation member 130 is phase-changed to the refrigerant in the vapor state, the pressure inside the evaporation member 130 becomes relatively high compared to the initial pressure, and the relative pressure of the evaporation member 130 Due to the increased pressure, the refrigerant in the vapor state is moved to the absorbing member 140.

Then, the refrigerant in the vapor state moved to the absorbent member 140 is absorbed by the absorbent accommodated inside the absorbent member 140 and is phase-changed into the refrigerant in the liquid state, and the refrigerant in the phase-changed liquid state is The absorbent liquid is formed while being mixed with the absorbent in the absorbent member 140.

At this time, in the absorption member 140, the refrigerant in the vapor state is formed as a refrigerant in the liquid state, so that the relatively low concentration in the absorption type refrigeration device 100 to which the reverse osmosis filter member is applied, that is, in a rare state The absorbent liquid is formed.

Then, the absorbent liquid in the rare state is moved to the reverse osmosis filter member 150 connected to the absorbent member 140.

Then, a part of the refrigerant in the liquid state constituting the absorbent liquid in the rare liquid state moved to the reverse osmosis filter member 150 is separated by the pressure applied from the pressurizing portion 158.

At this time, a portion of the refrigerant in the liquid state is separated from the absorbent liquid moved to the reverse osmosis filter member 150, so that the absorbent liquid is in a concentrated liquid state transferred from the regeneration member 110 to the absorbent member 140. The absorbent liquid in the intermediate liquid state is relatively low compared to the concentration of the absorbent liquid in a rare state, which is relatively low compared to the absorbent liquid, and moved from the absorbent member 140 to the reverse osmosis filter member 150.

Then, some of the refrigerant in the liquid state separated from the absorbent liquid is moved to the evaporation member 130 through the evaporation member side connector 156 and at the same time, the absorbent liquid in the intermediate liquid state is connected to the regeneration member side It is moved to the regeneration member 110 through (157).

At this time, when the refrigerant in the liquid state separated from the absorbent liquid is moved to the evaporation member 130, the absorbent may be moved to the evaporation member 130 together with the refrigerant in the liquid state, and the evaporation member The absorbent moved together to 130 is stacked on the inside of the evaporation member 130.

The control unit compares the amount of the absorbent stacked and the amount of the absorbent preset in the control unit, and if the amount of the stacked absorbent is relatively larger than the preset amount of the absorbent, the control unit controls the absorbing member side valve 160 ), and accordingly, the absorbent stacked inside the evaporation member 130 moves to the absorbent member 140 by tilting the absorbent member side valve 160.

As described above, the absorption type refrigeration device 100 to which the reverse osmosis filter member is applied is

The regeneration member is applied to an absorption refrigeration device capable of cooling and heating by a refrigerant moving while being phase-changed inside the absorption refrigeration device 100 to which the reverse osmosis filter member is applied and an absorbent absorbing the phase-change refrigerant. 110, the condensation member 120, the evaporation member 130, the absorption member 140 and the reverse osmosis filter member 150, the absorption member 140 in the reverse osmosis filter member ( When a portion of the refrigerant in the liquid state constituting the absorbent liquid moved to 150) is separated by the reverse osmosis filter member 150 and moved to the evaporation member 130, the liquid state constituting the absorbent liquid The absorbent liquid in which some of the refrigerant is separated is moved to the regeneration member 110 and corresponds to the amount of the absorbent liquid transferred to the regeneration member 110 after some of the refrigerant in the liquid state constituting the absorbent liquid is separated. By supplying only the thermal energy to the regeneration member 110, it is possible to relatively increase the performance coefficient defined by the ratio of the efficiency to the supplied thermal energy.

Hereinafter, an absorption type refrigeration device to which a reverse osmosis filter member according to other embodiments of the present invention is applied will be described with reference to the drawings.

In carrying out such a description, a description overlapping with the contents already described in the first embodiment of the present invention described above is replaced with it, and will be omitted here.

3 is a configuration diagram showing a state of the absorption type refrigeration device to which the reverse osmosis filter member according to the second embodiment of the present invention is applied.

Referring to FIG. 3, the absorption type refrigeration device 200 to which the reverse osmosis filter member according to the present embodiment is applied is cooled and heated by a refrigerant moving therein while being phase-changed and an absorbent absorbing the phase-changed refrigerant. Applicable to the absorption absorption refrigeration device as possible, and includes a regeneration member 210, a condensation member 220, an evaporation member 230, an absorption member 240, and a reverse osmosis filter member 250.

The regeneration member 210 transfers thermal energy supplied from the outside to the absorbent liquid in which the coolant in the liquid state and the absorbent are mixed to phase change the coolant in the liquid state into a vapor state.

Reference numeral 211 denotes the absorbent separated from the absorbent liquid due to the phase change of the refrigerant in the liquid state constituting the absorbent liquid in the regeneration member to the refrigerant in the vapor state, the absorbent member 240, more precisely the absorbent member It is an absorbent transfer tube constituting 240 and moved to the first absorbing portion 241 to be described later.

The condensation member 220 is connected to the regeneration member 210 to condense the refrigerant in the vapor state moved from the regeneration member 210 to phase change to the refrigerant in the liquid state.

The evaporation member 230 is connected to the condensation member 220 to evaporate the refrigerant in the liquid state moved from the condensation member 220 to phase change to the refrigerant in the vapor state.

The absorbent member 240 accommodates the absorbent therein, and the refrigerant in the vapor state moved from the evaporation member 230 is absorbed by the absorbent, so that the refrigerant in the vapor state changes to the refrigerant in the liquid state. Accordingly, an absorbent liquid in which the refrigerant in the liquid state and the absorbent are mixed is formed.

The reverse osmosis filter member 250 is connected between the absorption member 240 and the regeneration member 210, and separating a portion of the refrigerant in a liquid state from the absorption liquid formed by the absorption member 240, thereby The concentration of the absorbent liquid inside the reverse osmosis filter member 250 is increased relative to the concentration of the absorbent liquid moved from the absorbent member 240.

The evaporation member 230 includes a first evaporation part 231 and a second evaporation part 232.

Prior to detailed description, in this embodiment, for convenience of description, the refrigerant in the liquid state moved from the condensation member 220 to the first evaporator 231 is defined as a first liquid refrigerant, and the reverse osmosis filter The refrigerant in the liquid state moved from the member 250 to the second evaporator 232 is defined as a second liquid refrigerant.

The first evaporation unit 231 evaporates the refrigerant in the liquid state moved from the condensation member 220, that is, the first liquid refrigerant to phase change to the refrigerant in the vapor state.

The second evaporation unit 232 is connected to the first evaporation unit 231 and the refrigerant in the liquid state moved from the condensation member 220, that is, the first liquid refrigerant and the reverse osmosis filter member 250 In the liquid phase separated from the refrigerant, that is, the second liquid refrigerant is evaporated in a mixed state to phase change to the refrigerant in the vapor state.

The refrigerant in the liquid state inside the evaporation member 230 that is heat-exchanged with cold water supplied from the outside should maintain a purity higher than a certain standard, and the second evaporation part 232 from the absorbent liquid in the reverse osmosis filter member 250 ) When the liquid-state refrigerant is moved, when the absorbent in the absorbent liquid is moved together, the liquid-state refrigerant inside the second evaporator 232 cannot maintain purity of a certain standard, and accordingly, During the heat exchange between the cold water and the refrigerant in the liquid state inside the second evaporator 232, the cold water cannot be cooled to a required temperature.

In this embodiment, the cold water is first heat exchanged with the refrigerant in the liquid state moved from the reverse osmosis filter member 250 to the second evaporation unit 232, and then the first in the condensation member 220. By secondary heat exchange with the refrigerant in the liquid state moved to the evaporation unit 231, the cold water can be cooled to a required temperature.

For example, if the cooling temperature of the cold water, which is supplied from the outside to 12° C. and is required, is 7° C., the cold water at 12° C. supplied from the outside exchanges heat with the second evaporator 232 and is firstly brought to 10° C. After being cooled, it is moved toward the first evaporation part 231, and the cold water of the moved 10° C. is cooled to 7° C., which is a required cooling temperature while exchanging heat with the first evaporation part 231, and then the first It is discharged from the evaporation unit 231.

The absorbent member 240 includes the first absorbent portion 241 and the second absorbent portion 242.

The first absorber 241 accommodates the absorbent therein, and the refrigerant in the vapor state moved from the first evaporator 231 is absorbed by the absorbent, whereby the refrigerant in the vapor state is in the liquid state. It is phase-changed into a refrigerant, thereby forming a first absorbent liquid in which the refrigerant in the liquid state and the absorbent are mixed.

The second absorber 242 accommodates the absorbent therein, and the refrigerant in the vapor state moved from the second evaporator 232 is absorbed by the absorbent so that the refrigerant in the vapor state is in the liquid state. A phase change to a refrigerant is formed, thereby forming a second absorbent liquid in which the coolant in the liquid state and the absorbent are mixed, and connected to the first absorber 241 to be mixed with the first absorbent liquid.

In addition, the first absorbent liquid and the second absorbent liquid mixed in the second absorbent unit 242 are moved to the reverse osmosis filter member 250.

Meanwhile, an absorbing member side valve 260 is connected between the second evaporation unit 232 and the second absorption unit 242.

When the valve 260 on the absorbing member side is closed, when the refrigerant in the liquid state separated from the reverse osmosis filter member 250 is moved to the second evaporation unit 232, the reverse osmosis filter member 250 is unable to move. After the absorbent mixed with the refrigerant in the liquid state separated from the reverse osmosis filter member 250 in a separated state and moved to the second evaporator 232 is moved together, the second evaporator 232 Stacked inside.

In addition, when the absorbing member side valve 260 is opened, the absorbent stacked inside the second evaporation unit 232 is moved to the second absorbing unit 242 via the absorbing member side valve 260. .

Reference numeral 235 separates the first evaporation unit 231 and the first absorption unit 241, so that the refrigerant in the vapor state can be moved from the first evaporation unit 231 to the first absorption water. It is the first partition wall to which a certain space is connected.

Reference numeral 236 denotes the evaporation so that heat exchange between the refrigerant in the liquid state in the evaporation member 230 that is not evaporated in the evaporation member 230 and the absorption liquid present in the absorption member 240 is prevented. It is a heat exchange prevention wall separating the lower space of the member 230 and the lower space of the absorbent member 240.

Reference numeral 237 separates the second evaporation unit 232 and the second absorption unit 242, so that the refrigerant in the vapor state can be moved from the second evaporation unit 232 to the second absorption water. It is the second partition wall to which a certain space is connected.

4 is a configuration diagram showing a state of the absorption type refrigeration device to which the reverse osmosis filter member according to the third embodiment of the present invention is applied.

Referring to FIG. 4, the absorption refrigeration device 300 to which the reverse osmosis filter member 350 according to the present embodiment is applied is cooled by a refrigerant moving therein while being phase-changed and an absorbent absorbing the phase-changed refrigerant. And as applied to an absorption refrigeration device capable of heating, and includes an evaporation member 330, an absorption member 340, and a reverse osmosis filter member 350.

The evaporation member 330 is connected to the reverse osmosis filter member 350 and is separated from the absorbent liquid contained in the reverse osmosis filter member 350 by the reverse osmosis filter member 350 and moved to the evaporation member 330 It is to evaporate the refrigerant in the liquid state to phase change to the refrigerant in the vapor state.

The absorbing member 340 accommodates the absorbent therein, and the refrigerant in the vapor state moved from the evaporation member 330 is absorbed by the absorbent, so that the refrigerant in the vapor state changes to the refrigerant in the liquid state. Accordingly, an absorbent liquid in which the refrigerant in the liquid state and the absorbent are mixed is formed.

The reverse osmosis filter member 350 separates the refrigerant in a liquid state from the absorbing liquid formed in the absorbing member 340.

The reverse osmosis filter member 350 separates a portion of the refrigerant in a liquid state from the absorption liquid formed by the absorption member 340 to thereby reduce the concentration of the absorption liquid inside the reverse osmosis filter member 350 to the absorption member ( It is relatively high compared to the concentration of the absorbent liquid moved in 340).

After the formed in the absorbing member 340, a part of the refrigerant in a liquid state constituting the absorbing liquid that is moved to the reverse osmosis filter member 350 is separated from the reverse osmosis filter member 350 and the evaporation member 330 When being moved to, the absorbent liquid in which some of the refrigerant in the liquid state constituting the absorbent liquid is separated is moved to the absorbent member 340.

At this time, a portion of the refrigerant in the liquid state in the absorbent liquid in the reverse osmosis filter member 350 is moved to the absorption member 340, thereby moving from the reverse osmosis filter member 350 to the absorption member 340. The concentration of the absorbing liquid is relatively high compared to the concentration of the absorbing liquid transferred from the absorbing member 340 to the reverse osmosis filter member 350.

As described above, as the absorption refrigeration device 300 to which the reverse osmosis filter member 350 is applied includes the evaporation member 330, the absorption member 340, and the reverse osmosis filter member 350, from the outside The efficiency of the absorption refrigeration device 300 to which the reverse osmosis filter member 350 is applied can be relatively increased while minimizing the supplied thermal energy, as well as the absorption refrigeration device 300 to which the reverse osmosis filter member 350 is applied. The configuration can also be made simple.

Although the present invention has been illustrated and described in relation to specific embodiments, those skilled in the art variously modify the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. And can be changed. However, it is intended to clarify that all such modifications and variations are included within the scope of the present invention.

According to the absorption type refrigeration device to which the reverse osmosis filter member is applied according to an aspect of the present invention, only the thermal energy corresponding to the amount of the refrigerant in the liquid state transferred from the reverse osmosis filter member to the regeneration member is supplied to the regeneration member, thereby supplying Since the performance coefficient defined by the ratio of the efficiency to the thermal energy can be relatively increased, it is said that the industrial applicability is high.

100: absorption type refrigeration unit to which a reverse osmosis filter member is applied
110: regeneration member 120: condensation member
130: evaporation member 140: absorption member
150: reverse osmosis filter member 151: filter body
152: filter unit 153: absorption side mobile tube
154: refrigerant side moving tube 155: absorbing member side connecting tube
156: evaporation member side connector 157: regeneration member side connector
158: pressing portion 160: absorbing member side valve

Claims (5)

It is applied to an absorption type refrigeration device capable of cooling and heating by a refrigerant moving therein while being phase-changed and an absorbent absorbing the phase-changing refrigerant,
A regenerative member for transferring the thermal energy supplied from the outside to the absorbent liquid in which the refrigerant in the liquid state and the absorbent are mixed to phase-change the refrigerant in the liquid state into a vapor state;
A condensing member connected to the regeneration member to condense the refrigerant in a vapor state moved from the regeneration member to phase change to the liquid state refrigerant;
An evaporation member connected to the condensation member to evaporate the refrigerant in a liquid state moved from the condensation member to phase change to the refrigerant in a vapor state;
The refrigerant in the vapor state is accommodated therein, and the refrigerant in the vapor state moved from the evaporation member is absorbed by the absorbent, so that the refrigerant in the vapor state is phase-changed into the refrigerant in the liquid state, and accordingly, the refrigerant in the liquid state. An absorbent member in which an absorbent liquid in which the absorbent is mixed is formed; And
The concentration of the absorbent liquid therein is compared to the concentration of the absorbent liquid moved in the absorbent member by separating a portion of the refrigerant in the liquid state from the absorbent liquid formed by the absorbent member and connected between the absorbent member and the regeneration member. Relatively high reverse osmosis filter member; includes,
The absorbent liquid in the regeneration member is moved to the absorbent member, and a part of the coolant in the liquid state constituting the absorbent liquid is phase-changed to the coolant coolant and moved to the condensing member, and the condensing member is in a liquid state. The refrigerant that has been phase-changed is moved to the evaporation member, the refrigerant phase-changed from the evaporation member to a vapor state is moved to the absorption member, and the refrigerant phase-changed from the absorption member to a liquid state is mixed with the absorbent to After the absorbent liquid is formed, it is moved to the reverse osmosis filter member, and when a part of the refrigerant in the liquid state constituting the absorbent liquid is separated from the reverse osmosis filter member and moved to the evaporation member, the liquid state constituting the absorbent liquid The absorbent liquid from which some of the refrigerant is separated is moved to the regeneration member,
The concentration of the absorbent liquid transferred from the regeneration member to the absorbent member is relatively higher than the concentration of the absorbent liquid transferred from the reverse osmosis filter member to the regenerated member, and the concentration of the absorbent liquid moved from the reverse osmosis filter member to the regenerated member The concentration of the absorbent liquid is relatively high compared to the concentration of the absorbent liquid transferred from the absorbent member to the reverse osmosis filter member,
The amount of heat transferred from the reverse osmosis filter member to the evaporation member among the refrigerant in the liquid state and the amount of external heat energy supplied to the regeneration member so as to phase change from the regeneration member to the refrigerant in the vapor state are inversely proportional to each other. Accordingly, as the amount of the refrigerant in the liquid state constituting the absorbing liquid of the reverse osmosis filter member being moved to the evaporation member is relatively large, the thermal energy supplied from the outside may be relatively small. Absorption refrigeration unit with reverse osmosis filter element applied. delete According to claim 1,
Between the evaporating member and the absorbing member, an absorbing member side valve is connected,
When the valve on the absorption member side is closed, the refrigerant in the liquid state separated from the reverse osmosis filter member is separated from the reverse osmosis filter member in an unseparated state from the reverse osmosis filter member when the refrigerant is moved to the evaporation member, and the evaporation is performed. After the absorbent mixed together with the refrigerant in the liquid state moved to the member is moved together, it is laminated inside the evaporation member,
When the valve on the absorbing member side is opened, the absorbing refrigeration device to which the reverse osmosis filter member is applied is characterized in that the absorbent stacked inside the evaporating member is moved to the absorbing member via the absorbing member side valve. According to claim 1,
The evaporation member
A first evaporation unit for evaporating the refrigerant in the liquid state moved from the condensation member to phase change to the refrigerant in the vapor state;
It is connected to the first evaporator and the refrigerant in the liquid state moved from the condensation member and the refrigerant in the liquid state separated from the reverse osmosis filter member are mixed together to evaporate to change the phase to the refrigerant in the vapor state. 2 includes an evaporator,
The absorbent member
The refrigerant in the vapor state is accommodated therein, and the refrigerant in the vapor state moved from the first evaporator is absorbed by the absorber, and the refrigerant in the vapor state is phase-changed into the refrigerant in the liquid state, and accordingly the first evaporation A first absorbing part in which a first absorbent liquid in which the coolant in the vapor state moved from a part is mixed with the coolant in the liquid phase and the absorbent is formed,
The refrigerant in the vapor state is accommodated therein, and the refrigerant in the vapor state moved from the second evaporator is absorbed by the absorbent, and the refrigerant in the vapor state is phase-changed into the refrigerant in the liquid state, and accordingly the second evaporation And a second absorbing part in which a second absorbent liquid in which the coolant in the vapor state moved from a portion is mixed with the coolant in the liquid phase-changed state and the absorbent is formed,
The first absorbent portion and the second absorbent portion are connected to each other, so that the first absorbent liquid of the first absorbent portion is moved to the second absorbent portion and mixed with the second absorbent liquid to form the absorbent liquid, and the second absorbent portion is formed. The absorption liquid formed in the absorption type refrigeration device is applied to the reverse osmosis filter member, characterized in that is moved to the reverse osmosis filter member. delete

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