KR20200120186A - Absorption type chiller-heater - Google Patents

Abstract

The present invention relates to an absorption type cold/hot water machine that minimizes the loss of heat exchange efficiency that occurs as refrigerant condensed in a medium temperature regenerator flows into a low temperature regenerator. The absorption type cold/hot water machine may further include a liquid refrigerant guide line for guiding the liquid refrigerant separated in a gas-liquid separator to a condenser, and the gas-liquid separator is installed between the medium temperature regenerator and the low temperature regenerator.

Description

Absorption type chiller-heater {ABSORPTION TYPE CHILLER-HEATER}

The present invention relates to an absorption type cold or hot water machine.

Absorption type cold or hot water is a device that generates cold water or hot water having a predetermined temperature and supplies it, or cools or heats a predetermined space by using it. In general, absorption type cold and hot water machines include evaporators, absorbers, condensers and regenerators.

The absorption type cold/hot water machine can generate cold water or hot water having a predetermined temperature without using mechanical work such as a compressor by using a refrigerant and an absorbent. At this time, water is mainly used as a refrigerant and lithium bromide (LiBr) is mainly used as an absorbent.

Specifically, the refrigerant is evaporated in the evaporator, and the evaporated refrigerant is absorbed by the absorbent in the absorber. In addition, the absorbent having a lower concentration by absorbing the refrigerant may pass through at least one regenerator to be separated from the refrigerant, and at this time, the cold water flowing through the evaporator may be cooled by taking away heat by the latent heat of evaporation of the refrigerant.

On the other hand, the regenerator may include a high-temperature regenerator, a medium-temperature regenerator, and a low-temperature regenerator, and such an absorption type cold/hot water machine may be a triple efficiency absorption type cold/hot water machine. That is, the triple-efficiency absorption type cold and hot water heater can increase the efficiency by using the steam generated from the high-temperature regenerator as a heat source for the medium-temperature regenerator. However, in this case, after being used as a heat source in the medium temperature regenerator, the condensed refrigerant may move to the low-temperature regenerator together with the gaseous refrigerant regenerated in the medium-temperature regenerator, and the heat exchange efficiency decreases when the condensed refrigerant flows into the heat transfer pipe inside the low-temperature regenerator. There is.

An object of the present invention is to provide an absorption type cold/hot water machine that minimizes loss of heat exchange efficiency that occurs when a refrigerant condensed in a medium temperature regenerator flows into a low temperature regenerator.

An object of the present invention is to provide a cold/hot water dispenser with improved thermal efficiency supplied from a heat source device by forming a cycle such that the absorbent liquid discharged to the absorber passes through the high-temperature regenerator, the medium-temperature regenerator, and the low-temperature regenerator in that order.

Absorption type cold and hot water according to an embodiment of the present invention is generated from an evaporator in which refrigerant is evaporated, an absorber that absorbs the refrigerant evaporated from the evaporator into an absorbent, a high-temperature regenerator that vaporizes the refrigerant from the absorbent liquid supplied to the inside through a high-temperature gas, and a high-temperature regenerator. A medium temperature regenerator that vaporizes the refrigerant from the absorbent liquid supplied to the inside through the condensation heat of the gaseous refrigerant, a low temperature regenerator that vaporizes the refrigerant from the absorbent liquid supplied internally through the condensation heat of the gaseous refrigerant generated from the medium temperature regenerator, and the gas phase refrigerant generated from the low-temperature regenerator A gas-liquid separator for separating the liquid refrigerant may be installed between the medium-temperature regenerator and the low-temperature regenerator.

It may further include a liquid refrigerant guide line for guiding the liquid refrigerant separated in the gas-liquid separator to the condenser.

The liquid refrigerant guide line may be connected between the condenser and the gas-liquid separator.

The liquid refrigerant guide line may be connected between the gas-liquid separator and the condenser inlet line connecting between the low temperature regenerator and the condenser.

Between the medium-temperature regenerator and the low-temperature regenerator, a first medium-temperature regenerator refrigerant outlet line connecting the outlet of the heat transfer unit of the medium-temperature regenerator and the inlet of the low-temperature regenerator, and a second medium temperature connecting the steam space of the medium-temperature regenerator and the inlet of the low-temperature regenerator. A regenerator refrigerant outlet line is formed, and a gas-liquid separator may be installed in the first medium temperature refrigerant refrigerant outlet line.

Between the medium-temperature regenerator and the low-temperature regenerator, a first medium-temperature regenerator refrigerant outlet line connecting the outlet of the heat transfer unit of the medium-temperature regenerator and the inlet of the low-temperature regenerator, and a device connecting the steam space and outlet of the medium-temperature regenerator and the inlet of the low-temperature regenerator. 2 The medium temperature regenerator refrigerant outlet line is formed, and the gas-liquid separator may be installed at the outlet of the heat transfer unit of the medium temperature regenerator.

Between the medium-temperature regenerator and the low-temperature regenerator, a first medium-temperature regenerator refrigerant outlet line connecting the outlet of the heat transfer unit of the medium-temperature regenerator and the inlet of the low-temperature regenerator, and a device connecting the steam space and outlet of the medium-temperature regenerator and the inlet of the low-temperature regenerator. 2 The medium temperature regenerator refrigerant outlet line is formed, and the gas-liquid separator may be installed at the inlet of the heat transfer unit inside the low temperature regenerator.

Between the medium temperature regenerator and the low temperature regenerator, a first medium temperature regenerator refrigerant outlet line connecting the outlet of the heat transfer unit of the medium temperature regenerator and the inlet of the low temperature regenerator is formed, and the gas-liquid separator is installed on the refrigerant outlet line of the first medium temperature regenerator, and the first A second medium temperature regenerator refrigerant outlet line may be formed to connect a point between the inlet of the heat transfer unit of the gas-liquid separator and the low temperature regenerator among the refrigerant outlet lines of the medium temperature regenerator and a vapor space of the medium temperature regenerator.

The absorbent liquid discharged from the absorber is supplied to the high-temperature regenerator, the absorbent liquid discharged from the high-temperature regenerator is supplied to the medium-temperature regenerator, the absorbent liquid discharged from the medium-temperature regenerator is supplied to the low-temperature regenerator, and the absorbent liquid discharged from the low-temperature regenerator can be supplied to the absorber. have.

A low-temperature heat exchanger that heat-exchanges the absorbent liquid discharged from the absorber and the absorbent liquid discharged from the low-temperature regenerator, a medium-temperature heat exchanger that heat-exchanges the absorbent liquid that has passed through the low-temperature heat exchanger and the absorbent liquid discharged from the medium-temperature regenerator, and the absorbent liquid that has passed through the medium-temperature heat exchanger and discharged from the high-temperature regenerator It may further include a high-temperature heat exchanger for heat exchange of the absorbed liquid, and a refrigerant heat exchanger for heat-exchanging the absorbent liquid discharged from the absorber and the refrigerant discharged from the low temperature regenerator.

According to an embodiment of the present invention, the gas-liquid separator can minimize the inflow of liquid refrigerant into the low-temperature regenerator, and accordingly, there is an advantage in that the heat exchange efficiency of the heat transfer unit of the low-temperature regenerator can be increased.

1 is a view showing an absorption type cold or hot water dispenser according to an embodiment of the present invention.
FIG. 2 is a view showing the installation of the medium temperature regenerator and the low temperature regenerator shown in FIG. 1.
3 is a view showing an absorption type cold or hot water heater according to a parallel flow cycle according to an embodiment of the present invention.
4 is a view showing an absorption type cold/hot water machine according to a reverse flow cycle according to an embodiment of the present invention.
5 shows an absorption type cold/hot water dispenser according to a first modified reverse flow cycle according to an embodiment of the present invention.
6 shows an absorption type cold/hot water heater according to a second modified reverse flow cycle according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail together with the drawings.

1 is a view showing an absorption type cold or hot water dispenser according to an embodiment of the present invention.

The absorption cold and hot water heater according to an embodiment of the present invention may include an evaporator 10, an absorber 20, a condenser 30, a low-temperature regenerator 40, a medium-temperature regenerator 50, and a high-temperature regenerator 60.

The absorption type hot and cold water machine may include a plurality of shells. As shown in FIG. 1, the evaporator 10, the absorber 20, the condenser 30, the low-temperature regenerator 40, the medium-temperature regenerator 50, and the high-temperature regenerator 60 may be provided in separate shells. . However, this is only an example and is not limited thereto. As an example, the evaporator 10 and the absorber 20 may be provided in one shell, and the condenser 30 and the low-temperature regenerator 40 may be provided in another shell.

The refrigerant or absorbent flows through the evaporator 10, the absorber 20, the condenser 30, the low temperature regenerator 40, the medium temperature regenerator 50, and the high temperature regenerator 60. In this case, water may be used as the refrigerant and lithium bromide (LiBr) may be used as the absorbent.

In addition, the absorption cold/hot water heater may further include a heat source device (not shown) that directly burns city gas (LNG) as a combustion heat generating source. That is, the absorption type cold/hot water dispenser according to an embodiment of the present invention uses a combustion heat source and corresponds to a triple-effect absorption type cold/hot water dispenser equipped with three regenerators.

Hereinafter, each configuration will be described in detail.

The refrigerant evaporated in the evaporator 10 may flow to the absorber 20. According to an embodiment, as shown in FIG. 1, the evaporator 10 and the absorber 20 are provided separately in each shell, and a separate refrigerant evaporated from the evaporator 10 is guided to the absorber 20. Can be installed. According to another embodiment, the evaporator 10 and the absorber 20 are provided together in one shell, and an eliminator (not shown) capable of flowing a gaseous refrigerant is disposed between the evaporator 10 and the absorber 20. I can.

The evaporator 10 includes a refrigerant sprayer 12 for spraying a refrigerant, and a cold water pipe 14 through which cold water heat-exchanged with the refrigerant sprayed from the refrigerant sprayer 12 passes. At this time, since the evaporator 10 is maintained at a very low pressure, the injected refrigerant may be evaporated by the cold water flowing through the cold water pipe 14.

The cold water pipe 14 is connected to a cold water line 14a through which cold water flows into the evaporator 10 from the outside and a cold water line 14b through which the heat-exchanged cold water is discharged from the evaporator 10. For example, cold water introduced at 12 degrees from the cold water inlet line 14a may be discharged to the cold water line 14b at 7 degrees through heat exchange in the cold water pipe 14.

Looking at the flow of cold water, it flows to the cold water import line 14a, the cold water pipe 14, and the cold export water line 14b. This is described separately for convenience of explanation, and may be provided as a single pipe through which cold water flows.

The cold water flowing in this way and cooled to a predetermined temperature may be supplied to a cold water consumer (eg, a building). In addition, it is possible to cool the predetermined space by heat exchange between cold water and air in a predetermined space.

The refrigerant injector 12 is connected to the refrigerant circulation line 13 to receive a predetermined refrigerant and inject it into the evaporator 10. For example, the refrigerant injector 12 may be provided in the form of a tray having a plurality of fine openings. In addition, the refrigerant supplied from the refrigerant circulation line 13 falls through the fine opening and contacts the cold water pipe 14 to be evaporated.

The refrigerant circulation line 13 connects the lower portion of the evaporator 10 and the refrigerant sprayer 12 positioned above the evaporator 10. That is, the refrigerant circulation line 13 serves to move the refrigerant accumulated in the lower portion of the evaporator 10 to the upper portion. At this time, the refrigerant circulation line 13 is provided with a refrigerant pump 13a.

The refrigerant evaporated in the evaporator 10 flows into the absorber 20. The absorber 20 functions to absorb the introduced refrigerant into the absorbent.

Hereinafter, the absorbent liquid may mean a solution in which a refrigerant and an absorbent are mixed. However, this is merely an example for convenience of description and is not limited thereto.

The absorber 20 is provided with an absorbent sprayer 22 for injecting an absorbent. The absorber injector 22 may be connected to the absorber inlet line 25 to receive a predetermined absorbent. The structure of the absorbent injector 22 may be provided in the same manner as the structure of the refrigerant injector 12 described above.

As the refrigerant introduced into the absorber 20 is absorbed by the absorbent injected from the absorbent injector 22, the concentration of the absorbent liquid may be lowered. The absorbent liquid having a lower concentration may be accommodated in the lower portion of the absorber 20 and may be discharged to the outside of the absorber 20 through the absorber discharge line 23. At this time, the absorber discharge line 23 is provided with an absorber outlet pump 23a.

Further, the absorber 20 is provided with an absorption cooling water pipe 24 through which cooling water passes. The coolant may receive heat generated by absorbing the refrigerant by the absorbent.

The absorption cooling water pipe 24 is connected to a cooling water receiving line 24a through which cooling water flows into the absorber 20 from the outside and a cooling water connection line 24b through which the heat-exchanged cooling water is discharged from the absorber 20. For example, the cooling water flowing into the cooling water receiving line 24a at 32 degrees may be discharged to the cooling water connection line 24b at 34.5 degrees through heat exchange in the absorption cooling water pipe 24.

Meanwhile, the refrigerant separated by the low temperature regenerator 40 may flow to the condenser 30. According to an embodiment, as shown in FIG. 1, the low temperature regenerator 40 and the condenser 30 are provided separately in each shell, and the refrigerant separated from the low temperature regenerator 40 is guided to the condenser 30. A separate pipe can be installed. According to another embodiment, the low temperature regenerator 40 and the condenser 30 are provided together in one shell, and an eliminator (not shown) capable of flowing a gas phase refrigerant between the low temperature regenerator 40 and the condenser 30 is provided. Can be placed.

The condenser 30 is provided with a condensed cooling water pipe 34 through which the cooling water passes. The cooling water may receive heat generated by condensing the refrigerant.

The condensed cooling water pipe 34 is connected to a cooling water connection line 24b through which cooling water flows into the condenser 30 and a cooling water discharge line 34a through which cooling water is discharged to the outside. For example, the cooling water introduced at 34.5 degrees from the cooling water connection line 24b may be discharged at 37 degrees through the cooling water discharge line 34a.

Looking at the flow of the cooling water, it flows to the cooling water receiving water line 24a, the absorption cooling water pipe 24, the cooling water connection line 24b, the condensing cooling water pipe 34, and the cooling water discharge line 34a. This is described separately for convenience of explanation, and may be provided as a single pipe through which cooling water flows.

The cooling water flowing in this way and receiving predetermined heat may flow to a cooling tower or the like to release heat. The cooling water that has released heat may be introduced into the cooling water receiving water line 24a and circulated again.

In addition, the condenser 30 is connected to the evaporator 10 and the condensed refrigerant supply line 33. The refrigerant condensed in the condenser 30 may be supplied to the evaporator 10 through the condensed refrigerant supply line 33. At this time, various valves (not shown) may be installed in the condensed refrigerant supply line 33.

The low-temperature regenerator 40 is connected to a first condenser inlet line 43 and a second condenser inlet line 41 for transferring the refrigerant to the condenser 30. In summary, from the low temperature regenerator 40 to the condenser 30, the liquid refrigerant may flow through the first condenser inlet line 43, and the gaseous refrigerant may flow through the second condenser inlet line 41. On the other hand, when the low-temperature regenerator 40 and the condenser 30 are provided together in one shell, the gaseous refrigerant may flow through an eliminator (not shown).

The absorber discharge line 23 may be branched into a first heat exchanger passage line 71 and a refrigerant heat exchanger passage line 72. The low-concentration absorbent liquid branched into the first heat exchanger passage line 71 may flow into the second heat exchanger passage line 73 after heat exchange with the low temperature regenerator discharge line 42 in the low temperature heat exchanger 70. The low temperature heat exchanger 70 may perform heat exchange between the absorbent liquid discharged from the absorber 20 and the absorbent liquid discharged from the low temperature regenerator 40.

The low-concentration absorbent liquid branched into the refrigerant heat exchanger passage line 72 may flow into the second heat exchanger passage line 73 after heat exchange with the first condenser inlet line 43 in the refrigerant heat exchanger 100. The refrigerant heat exchanger 100 may exchange heat between the absorbent liquid discharged from the absorber 20 and the refrigerant discharged from the low temperature regenerator 40.

The first heat exchanger passage line 71 and the refrigerant heat exchanger passage line 72 may pass through different heat exchangers and then be joined to the second heat exchanger passage line 73.

The second heat exchanger passage line 73 may flow into the third heat exchanger passage line 75 after heat exchange with the medium temperature regenerator discharge line 52 in the medium temperature heat exchanger 80. The medium temperature heat exchanger 80 may heat exchange the absorbent liquid that has passed through the low temperature heat exchanger 70 and the absorbent liquid discharged between the medium temperature regenerator 50.

The third heat exchanger passage line 75 may flow into the high-temperature regenerator inlet line 77 after heat exchange with the high-temperature regenerator discharge line 62 in the high-temperature heat exchanger 90. The high-temperature heat exchanger 90 may heat-exchange the absorbent liquid that has passed through the medium-temperature heat exchanger 80 and the absorbent liquid discharged from the high-temperature regenerator 60.

Looking at the flow of the low-concentration absorbent liquid, the absorber discharge line 23, the first heat exchanger passage line 71 or the refrigerant heat exchanger passage line 72, the second heat exchanger passage line 73, and the third heat exchanger passage line (75) and the high temperature regenerator inlet line (77). This is separately described for convenience of description, and may be provided as a single tube through which the low-concentration absorbent liquid flows.

The absorption type cold/hot water dispenser may further include a heat source device (not shown), and the heat source device (not shown) may supply a hot gas to the high temperature regenerator 60. The high-temperature regenerator 60 may be heated by a high-temperature gas, and in this case, the refrigerant may evaporate from the low-concentration absorbent liquid supplied into the high-temperature regenerator 60 through the high-temperature regenerator inlet line 77.

That is, the high-temperature regenerator 60 may regenerate the refrigerant by vaporizing the refrigerant from the absorbent liquid supplied therein. The hot regenerator 60 may be heated to about 200°C.

A high-temperature regenerator refrigerant outlet line 63 and a high-temperature regenerator discharge line 62 may be connected to the high-temperature regenerator 60.

The high-temperature regenerator refrigerant outlet line 63 may connect the high-temperature regenerator 60 and the medium-temperature regenerator 50. The vapor phase refrigerant evaporated from the high temperature regenerator 60 may flow from the high temperature regenerator 60 to the medium temperature regenerator 50 through the high temperature regenerator refrigerant outlet line 63.

The high-temperature regenerator discharge line 62 may connect the high-temperature regenerator 60 and the medium-temperature regenerator 50. The absorption liquid from which the refrigerant is evaporated in the high-temperature regenerator 60 may flow from the high-temperature regenerator 60 to the medium-temperature regenerator 50 through the high-temperature regenerator discharge line 62.

The medium temperature regenerator 50 may be connected to a high temperature regenerator refrigerant outlet line 63, a high temperature regenerator discharge line 62, and a medium temperature regenerator discharge line 52.

The gaseous refrigerant generated from the high temperature regenerator 60 may be supplied to the medium temperature regenerator 50 through the refrigerant outlet line 63 of the high temperature regenerator. The medium temperature regenerator 50 may vaporize the refrigerant from the absorbed liquid supplied to the inside through condensation heat of the gaseous refrigerant generated in the high temperature regenerator 60. The medium temperature regenerator 50 may be heated to about 130°C by condensation heat of the gaseous refrigerant generated in the high temperature regenerator 60.

Specifically, the gaseous refrigerant supplied from the high-temperature regenerator 60 to the mid-temperature regenerator 50 may be partially condensed because the temperature of the gaseous refrigerant supplied to the mid-temperature regenerator 50 is reduced by the absorption liquid inside the mid-temperature regenerator 50. In this case, heat generated when the gaseous refrigerant condenses may heat the absorbent liquid inside the medium temperature regenerator 50 to vaporize the refrigerant from the absorbent liquid. Accordingly, the concentration of the absorbent liquid supplied into the medium temperature regenerator 50 through the high temperature regenerator discharge line 62 may be increased.

The absorbent liquid having a higher concentration in the medium temperature regenerator 50 may be supplied to the low temperature regenerator 40 through the medium temperature regenerator discharge line 52.

The low temperature regenerator 40 includes a medium temperature regenerator refrigerant outlet line 53, a medium temperature regenerator discharge line 52, a low temperature regenerator discharge line 42, a first condenser inlet line 43 and a second condenser inlet line 41. ) Can be connected.

The low-temperature regenerator 40 may be supplied with a gaseous refrigerant generated from the mid-temperature regenerator 50 through the mid-temperature regenerator refrigerant outlet line 53. The low-temperature regenerator 40 may vaporize the refrigerant from the absorption liquid supplied to the inside through condensation heat of the gaseous refrigerant generated in the medium-temperature regenerator 50. The low temperature regenerator 40 may be heated to about 70°C by the heat of condensation of the gaseous refrigerant generated in the medium temperature regenerator 50.

Specifically, the gaseous refrigerant supplied from the medium temperature regenerator 50 to the low temperature regenerator 40 may be partially condensed because the temperature of the gaseous refrigerant supplied to the low temperature regenerator 40 is reduced by the absorption liquid inside the low temperature regenerator 40. In this case, the heat generated when the gaseous refrigerant condenses may heat the absorption liquid inside the low-temperature regenerator 40 to vaporize the refrigerant from the absorption liquid. Accordingly, the concentration of the absorbent liquid supplied into the low temperature regenerator 40 through the medium temperature regenerator discharge line 52 may be higher.

The absorbent liquid having a higher concentration in the low-temperature regenerator 40 flows to the low-temperature regenerator discharge line 42, and the absorbent liquid flowing to the low-temperature regenerator discharge line 42 flows to the absorber 20 through the absorber inlet line 25. I can. The low temperature regenerator discharge line 42 may be connected to the absorber inlet line 25.

As shown in Figure 1, the absorbent liquid discharged from the absorber 20 is supplied to the high temperature regenerator 60 to regenerate the refrigerant, and the absorbent liquid discharged from the high temperature regenerator 60 is supplied to the medium temperature regenerator 50 to provide the refrigerant. The refrigerant is regenerated and the absorbent liquid discharged from the medium temperature regenerator 50 is supplied to the low temperature regenerator 40 to regenerate the refrigerant, and the absorbent liquid discharged from the low temperature regenerator 40 is supplied to the absorber 20 in a series flow cycle. According to this, there is an advantage of improving the efficiency of using heat supplied from a heat source device (not shown).

Meanwhile, a gas-liquid separator 59 may be installed at the refrigerant outlet line 53 of the medium temperature regenerator. A gaseous refrigerant and a liquid refrigerant may be introduced into the low temperature regenerator 40 together through the refrigerant outlet line 53 of the medium temperature regenerator, and the gaseous refrigerant is a refrigerant evaporated from the absorbed liquid by the heat of condensation in the medium temperature regenerator 50, and the liquid refrigerant is The gas phase refrigerant of the medium temperature regenerator 50 may be a condensed refrigerant. When the liquid refrigerant flows into the low temperature regenerator 40, the liquid refrigerant may flow into the heat transfer unit of the low temperature regenerator 40. When the liquid refrigerant flows into the heat transfer unit, heat exchange efficiency in the heat transfer unit may be reduced by reducing the heat transfer area required for latent heat exchange.

Accordingly, a method of minimizing the inflow of refrigerant from the middle temperature regenerator 50 to the low temperature regenerator 40 through the middle temperature regenerator refrigerant outlet line 53 may be required.

A gas-liquid separator 59 for separating a liquid refrigerant may be installed between the medium-temperature regenerator 50 and the low-temperature regenerator 40 in the absorption cold/hot water heater according to an embodiment of the present invention. In addition, the absorption type cold/hot water dispenser may include a liquid refrigerant guide line 55 for guiding the liquid refrigerant separated by the gas-liquid separator 59 to the condenser 30.

The liquid refrigerant guide line 55 may be connected between the gas-liquid separator 59 and the condenser 30.

The gas-liquid separator 59 separates the liquid refrigerant from the refrigerant flowing from the medium temperature regenerator 50, flows the liquid refrigerant to the condenser 30 through the liquid refrigerant guide line 55, and transfers the gas phase refrigerant to the medium temperature refrigerant outlet line. It can flow to the low temperature regenerator 40 through 53. In this case, the flow of the liquid refrigerant to the low temperature regenerator 40 can be minimized, and accordingly, loss of heat exchange efficiency of the heat transfer unit inside the low temperature regenerator 40 can be minimized.

Meanwhile, according to an embodiment, unlike FIG. 1, the liquid refrigerant guide line 55 may be connected between the gas-liquid separator 59 and the first condenser inlet line 43. The first condenser inlet line 43 may be a pipe that guides the liquid refrigerant condensed in the low temperature regenerator 40 to the condenser 30. Accordingly, the liquid refrigerant guide line 55 may guide the liquid refrigerant separated by the gas-liquid separator 59 to the condenser 30 through the first condenser inlet line 43. When the liquid refrigerant guide line 55 is connected to the first condenser inlet line 43, the pipe length may be shorter than that of the case where the liquid refrigerant guide line 55 is directly connected to the condenser 30, and in this case manufactured There is an advantage in cost reduction and structure simplification.

FIG. 2 is a view showing the installation of the medium temperature regenerator and the low temperature regenerator shown in FIG. 1.

Each of the medium temperature regenerator 50 and the low temperature regenerator 40 may include heat transfer units 153 and 143. Although not shown in FIG. 2, the high-temperature regenerator 60 may also have a heat transfer unit therein.

Each of the heat transfer unit 153 provided in the medium temperature regenerator 50 and the heat transfer unit 143 provided in the low temperature regenerator 40 are provided inside the regenerator, and the heat transfer units 153 and 143 may be heat transfer tubes.

Heat exchange between the absorbent liquid and the gaseous refrigerant may be performed in the heat transfer pipe. That is, the gaseous refrigerant is condensed to change into a liquid refrigerant, and the refrigerant may be evaporated by the heat of condensation in the absorbent liquid. The medium temperature regenerator 50 and the low temperature regenerator 40 may be provided with vapor spaces 151 and 154 in which gaseous refrigerants are accommodated.

The medium temperature regenerator 50 may be provided with a heat transfer unit inlet 152 and a heat transfer unit outlet 154. A heat transfer unit 153 may be disposed between the heat transfer unit inlet 152 and the heat transfer unit outlet 154.

Similarly, in the low temperature regenerator 40, a heat transfer unit inlet 142 and a heat transfer unit outlet 144 are formed, and a heat transfer unit 143 may be disposed between the heat transfer unit inlet 142 and the heat transfer unit outlet 144. .

The heat transfer unit inlet 152 may be connected to the refrigerant outlet line 63 of the high temperature regenerator. The heat transfer unit outlet 154 may be connected to the refrigerant outlet line 53 of the medium temperature regenerator.

According to an embodiment, the medium temperature regenerator refrigerant outlet line 53 may include a first medium temperature regenerator refrigerant outlet line 53a and a second medium temperature regenerator refrigerant outlet line 53b.

The first medium temperature regenerator refrigerant outlet line 53a connects the heat transfer unit outlet 153 of the medium temperature regenerator 50 to the heat transfer unit inlet 142 of the low temperature regenerator 40, and the second medium temperature regenerator refrigerant outlet line 53b The steam space 153 of the medium temperature regenerator 50 and the heat transfer unit inlet 142 of the low temperature regenerator 40 may be connected.

In this case, according to an embodiment, as shown in FIG. 2, the gas-liquid separator 59 may be installed in the refrigerant outlet line 53a of the first medium temperature regenerator. Meanwhile, in this case, the second medium temperature regenerator refrigerant outlet line 53 may be connected between the vapor space 151 of the medium temperature regenerator 50 and the heat transfer unit inlet 142 of the low temperature regenerator 40, but the second medium temperature The regenerator refrigerant outlet line 53 is a steam space of the medium-temperature regenerator 50 and a point between the gas-liquid separator 59 and the heat transfer unit inlet 142 of the low-temperature regenerator 40 among the first medium-temperature regenerator refrigerant outlet lines 53a. You can also connect 151.

According to another embodiment, unlike shown in FIG. 2, the gas-liquid separator 59 may be installed at the outlet 154 of the heat transfer unit of the medium temperature regenerator 50.

According to another embodiment, unlike shown in FIG. 2, the gas-liquid separator 59 may be installed at the inlet 142 of the heat transfer unit of the low temperature regenerator 40.

As described above, the absorption type cold/hot water dispenser according to an embodiment of the present invention has the advantage of minimizing the inflow of liquid refrigerant into the low temperature regenerator 40 by using a gas-liquid separator to minimize the reduction of the heat exchange area, thereby minimizing heat exchange efficiency loss. have.

Various embodiments for minimizing the liquid refrigerant flowing from the medium temperature regenerator 50 to the low temperature regenerator 40 as described above may be applied irrespective of the flow cycle of the absorbent liquid in the absorption cold/hot water heater. 3 to 6 are diagrams for explaining various cycles of the absorption type cold/hot water dispenser to which various embodiments for minimizing the liquid refrigerant flowing from the medium temperature regenerator 50 to the low temperature regenerator 40 described above are applicable. However, since the cycle of the absorption cold/hot water dispenser shown in FIGS. 3 to 6 is also exemplary for convenience of description, various embodiments for minimizing the liquid refrigerant flowing from the medium temperature regenerator 50 to the low temperature regenerator 40 are Applicable to all absorption type cold and hot water machines.

3 is a view showing an absorption type cold or hot water heater according to another embodiment of the present invention. 3 shows an absorption type cold/hot water dispenser according to a parallel flow cycle.

According to the parallel flow cycle, the absorbent liquid discharged from the absorber 20 may flow to the high temperature regenerator 60, the medium temperature regenerator 50, and the low temperature regenerator 40, respectively.

That is, some of the absorbent liquid that has passed through the first heat exchanger passage line 71 is supplied to the low-temperature regenerator 40 through the low-temperature regenerator inlet line 206, and is among the absorbent liquid that has passed through the second heat exchanger passage line 73. Some are supplied to the medium temperature regenerator 50 through the medium temperature regenerator inlet line 204, and the absorbent liquid that has passed through the third heat exchanger passage line 75 is supplied to the high temperature regenerator 60 through the high temperature regenerator inlet line 201 Can be.

After regenerating the refrigerant in the high-temperature regenerator 60, the absorbent liquid whose concentration is increased is discharged through the high-temperature regenerator discharge line 202 and guided to the absorber 20, and after regenerating the refrigerant in the medium-temperature regenerator 50, the concentration is further increased. The increased absorbent liquid is discharged through the medium-temperature regenerator discharge line 204 and then guided to the absorber 20, and after regenerating the refrigerant in the low-temperature regenerator 40, the high-concentration absorbent liquid is discharged through the low-temperature regenerator discharge line 205. After can be guided to the absorber 20.

In FIG. 3, the low temperature heat exchanger 70 exchanges heat between the absorbent liquid discharged from the absorber 20 and the absorbent liquid discharged from the high temperature regenerator 60, the medium temperature regenerator 50, and the low temperature regenerator 40, and the medium temperature heat exchanger 80 ) Heat exchange between the absorbent liquid that has passed through the low-temperature heat exchanger 70 and the absorbent liquid discharged from the high-temperature regenerator 60 and the medium-temperature regenerator 50, and the high-temperature heat exchanger 90 is the absorbent liquid that has passed through the medium-temperature heat exchanger 80. And heat exchange between the absorbent liquid discharged from the high temperature regenerator (60).

In addition, descriptions overlapping those described in FIGS. 1 to 2 will be omitted.

4 is a view showing an absorption type cold or hot water device according to another embodiment of the present invention. 4 shows an absorption type cold/hot water dispenser according to a reverse flow cycle.

According to the reverse flow cycle, the absorbent liquid discharged from the absorber 20 may flow in the low temperature regenerator 40, the medium temperature regenerator 50, and the high temperature regenerator 60 in that order.

That is, the absorbent liquid discharged from the absorber 20 through the absorber discharge line 23 is supplied to the low-temperature regenerator 40 through the low-temperature regenerator inlet line 303, and the concentration after the refrigerant is regenerated in the low-temperature regenerator 40 The increased absorption liquid may be discharged through the low temperature regenerator discharge line 304 and then supplied to the medium temperature regenerator 50 through the medium temperature regenerator inlet line 305. After the refrigerant is regenerated in the medium temperature regenerator 50, the absorbent liquid whose concentration is increased may be discharged through the medium temperature regenerator discharge line 306 and then supplied to the high temperature regenerator 60 through the high temperature regenerator inlet line 307.

After the refrigerant is regenerated in the high-temperature regenerator 60, the absorbent liquid whose concentration is increased may flow to the absorber 20 through the high-temperature regenerator discharge line 308.

The low temperature heat exchanger 70 exchanges heat between the absorbent liquid discharged from the absorber 20 and the absorbent liquid discharged from the high temperature regenerator 60 and passed through the high temperature heat exchanger 90 and the medium temperature heat exchanger 80. (80) heat exchange between the absorbent liquid discharged from the absorber 20 and passed through the low-temperature heat exchanger 70 and the absorbent liquid discharged from the high-temperature regenerator 60 and passed through the high-temperature heat exchanger 90, 90 may heat exchange between the absorbent liquid discharged from the absorber 20 and passed through the low temperature heat exchanger 70 and the medium temperature heat exchanger 80 and the absorbent liquid discharged from the high temperature regenerator 60.

In addition, descriptions overlapping those described in FIGS. 1 to 2 will be omitted.

5 is a view showing an absorption type cold or hot water heater according to another embodiment of the present invention. Fig. 5 shows an absorption type water heater according to a first modified reverse flow cycle.

According to the first modified reverse flow cycle, the absorbent liquid discharged from the absorber 20 may flow to the low temperature regenerator 40 and then flow to the medium temperature regenerator 50 or the high temperature regenerator 60, and in the low temperature regenerator 40 After the refrigerant is regenerated, the high-concentration absorbent liquid flows to the high-temperature regenerator 60 or the absorber 20, and after the refrigerant is regenerated in the medium-temperature regenerator 50 and the high-temperature regenerator 60, the absorber 20 Can flow into.

Specifically, the absorbent liquid discharged from the absorber 20 through the absorber discharge line 23 is separated and flowed into the first low-temperature regenerator inlet branch line 401 and the second low-temperature regenerator inlet branch line 402, and then flows. It may be introduced into the low temperature regenerator 40 through the inlet lamination line 403.

After the refrigerant is regenerated in the low-temperature regenerator 40, the absorbent liquid whose concentration is increased is discharged through the low-temperature regenerator discharge line 404 and then becomes the medium-temperature regenerator 50 through the medium-temperature regenerator inlet line 405, or the high-temperature regenerator inlet line ( It may be supplied to the hot regenerator 60 through 406. Meanwhile, after the refrigerant is regenerated in the low-temperature regenerator 40, at least a portion of the absorbent liquid whose concentration is increased may be introduced into the absorber 20 through the bypass line 405.

After the refrigerant is regenerated in the medium temperature regenerator 50, the absorbent liquid having a higher concentration may be discharged to the medium temperature regenerator discharge line 406 and then flow into the absorber 20 through the absorber inlet line 25.

After the refrigerant is regenerated in the high-temperature regenerator 60, the absorbent liquid having a high concentration may also be discharged to the high-temperature regenerator discharge line 408 and then flow into the absorber 20 through the absorber inlet line 25.

In addition, descriptions overlapping those described in FIGS. 1 to 2 will be omitted.

6 is a view showing an absorption type cold or hot water machine according to another embodiment of the present invention. 6 shows an absorption type water heater according to a second modified reverse flow cycle.

According to the second modified reverse flow cycle, the absorbent liquid discharged from the absorber 20 through the absorber discharge line 23 may be supplied to the low temperature regenerator 40 through the low temperature regenerator inlet line 502. After the refrigerant is regenerated in the low-temperature regenerator 40, the absorbent liquid whose concentration is increased is discharged through the low-temperature regenerator discharge line 503 and then supplied to the mid-temperature regenerator 50 through the mid-temperature regenerator inlet line 504, or the high-temperature regenerator inlet line It may be supplied to the high-temperature regenerator 60 through 505.

After the refrigerant is regenerated in the medium temperature regenerator 50, the absorbent liquid whose concentration is increased may be discharged through the medium temperature regenerator discharge line 506 and then flow into the absorber 20 through the absorber inlet line 25.

After the refrigerant is regenerated in the high-temperature regenerator 60, the absorbent liquid whose concentration is increased may be discharged through the high-temperature regenerator discharge line 507 and then flow into the absorber 20 through the absorber inlet line 25.

On the other hand, the low temperature regenerator 40, the medium temperature regenerator 50, and the high temperature regenerator 60 may be provided with water level regulators 40a, 50a, 60a for adjusting the level of the absorption liquid inside the regenerator.

In the absorption type cold/hot water dispenser shown in FIGS. 1 to 6, a valve, a pump, etc. may be installed in a pipe through which an absorbent liquid or a refrigerant flows, if necessary.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention.

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

10: evaporator 20: absorber
30: condenser 40: low temperature regenerator
50: medium temperature regenerator 55: liquid refrigerant guide line
59: gas-liquid separator 60: high temperature regenerator

Claims (10)

An evaporator from which the refrigerant is evaporated;
An absorber for absorbing the refrigerant evaporated in the evaporator into an absorbent;
A high-temperature regenerator for vaporizing a refrigerant from the absorbent liquid supplied to the inside through the high-temperature gas;
A medium-temperature regenerator for vaporizing the refrigerant from the absorbent liquid supplied to the inside through condensation heat of the gaseous refrigerant generated in the high-temperature regenerator;
A low-temperature regenerator for vaporizing the refrigerant from the absorbent liquid supplied to the inside through condensation heat of the gaseous refrigerant generated in the medium-temperature regenerator; And
And a condenser for cooling the gaseous refrigerant generated in the low temperature regenerator,
A gas-liquid separator for separating a liquid refrigerant is installed between the medium-temperature regenerator and the low-temperature regenerator.
Absorption type water heater. The method of claim 1,
Further comprising a liquid refrigerant guide line for guiding the liquid refrigerant separated in the gas-liquid separator to the condenser
Absorption type water heater. The method of claim 2,
The liquid refrigerant guide line
Connected between the condenser and the gas-liquid separator
Absorption type water heater. The method of claim 2,
The liquid refrigerant guide line
Connected between the gas-liquid separator and a condenser inlet line connecting between the low temperature regenerator and the condenser
Absorption type water heater. The method of claim 1,
Between the medium temperature regenerator and the low temperature regenerator
A first medium temperature regenerator refrigerant outlet line connecting the heat transfer unit outlet of the medium temperature regenerator and the heat transfer unit inlet of the low temperature regenerator,
A second medium temperature regenerator refrigerant outlet line is formed connecting the steam space of the medium temperature regenerator and an inlet of the heat transfer unit of the low temperature regenerator,
The gas-liquid separator
Installed in the refrigerant outlet line of the first medium temperature regenerator
Absorption type water heater. The method of claim 1,
Between the medium temperature regenerator and the low temperature regenerator
A first medium temperature regenerator refrigerant outlet line connecting the heat transfer unit outlet of the medium temperature regenerator and the heat transfer unit inlet of the low temperature regenerator,
A second medium temperature regenerator refrigerant outlet line is formed connecting the steam space and the outlet of the medium temperature regenerator and the inlet of the heat transfer unit of the low temperature regenerator,
The gas-liquid separator
Installed at the outlet of the heat transfer unit of the medium temperature regenerator
Absorption type water heater. The method of claim 1,
Between the medium temperature regenerator and the low temperature regenerator
A first medium temperature regenerator refrigerant outlet line connecting the heat transfer unit outlet of the medium temperature regenerator and the heat transfer unit inlet of the low temperature regenerator,
A second medium temperature regenerator refrigerant outlet line is formed connecting the steam space and the outlet of the medium temperature regenerator and the inlet of the heat transfer unit of the low temperature regenerator,
The gas-liquid separator
Installed at the entrance of the heat transfer unit inside the low temperature regenerator
Absorption type water heater. The method of claim 1,
Between the medium temperature regenerator and the low temperature regenerator
A first medium temperature regenerator refrigerant outlet line is formed connecting the heat transfer unit outlet of the medium temperature regenerator and the heat transfer unit inlet of the low temperature regenerator,
The gas-liquid separator
It is installed in the refrigerant outlet line of the first medium temperature regenerator,
A second medium-temperature regenerator refrigerant outlet line is formed between a point between the gas-liquid separator and the inlet of the low-temperature regenerator among the refrigerant outlet lines of the first medium-temperature regenerator and a vapor space of the medium-temperature regenerator.
Absorption type water heater. The method of claim 1,
The absorbent liquid discharged from the absorber is supplied to the high-temperature regenerator,
The absorbent liquid discharged from the high temperature regenerator is supplied to the medium temperature regenerator,
The absorbent liquid discharged from the medium temperature regenerator is supplied to the low temperature regenerator,
The absorbent liquid discharged from the low-temperature regenerator is supplied to the absorber.
Absorption type water heater. The method of claim 9,
A low temperature heat exchanger for exchanging heat between the absorbent liquid discharged from the absorber and the absorbent liquid discharged from the low temperature regenerator;
A medium temperature heat exchanger for exchanging heat between the absorbent liquid passing through the low temperature heat exchanger and the absorbent liquid discharged from the medium temperature regenerator;
A high temperature heat exchanger for exchanging heat between the absorbent liquid passing through the medium temperature heat exchanger and the absorbent liquid discharged from the high temperature regenerator; And
Further comprising a refrigerant heat exchanger for exchanging heat exchange between the absorbent liquid discharged from the absorber and the refrigerant discharged from the low temperature regenerator.
Absorption type water heater.

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