KR102144934B1 - absorption chiller using non-heat type recycling process - Google Patents

Abstract

The present invention relates to an absorption chiller using a non-heating type regeneration process, which includes: an evaporator and an absorption mechanism disposed to face each other while leaving an eliminator therebetween; a membrane that separates the converted dilute solution into a refrigerant and a concentrated solution by allowing the dilute solution converted by absorption of refrigerant gas in the absorption mechanism to pass therethrough; and a concentrated solution chamber that receives and stores the concentrated solution separated by the membrane, wherein the concentrated solution stored in the concentrated solution chamber is supplied to the absorption mechanism by a control signal, the refrigerant separated by the membrane is supplied to the evaporator. Moreover, the refrigerant circulating in the evaporation mechanism performs heat exchange with air passing through any one of heat exchangers, and is discharged at a temperature lower than the temperature at which the air is introduced.

Description

Absorption chiller using non-heat type recycling process}

The present invention relates to an absorption chiller, and more particularly, to avoid using a high-temperature heat source for regeneration of the absorbent liquid, excluding the configuration of the regenerator and condenser, and to regenerate the absorbent liquid in a non-heating manner, simplifying facilities as well as cooling water. It relates to an absorption chiller using a non-heating regeneration process that reduces the consumption of water and saves energy.

In general, absorption chillers use water as a refrigerant and use the heat of vaporization, which is heat absorbed from the surroundings, when water, which is a refrigerant, is evaporated.A cold water line is placed in an evaporator where the refrigerant is evaporated to cool the cold water by the evaporated refrigerant. It is a device.

Accordingly, the cold water in the cold water line is deprived of heat energy and the temperature is lowered, and the refrigerant absorbs the heat of vaporization from the cold water and evaporates.

Such an absorption chiller has a repetitive cycle in which the cold water flowing through the cold water line is cooled with the heat of vaporization when the refrigerant is evaporated, and the refrigerant evaporated by the heat of vaporization is condensed with external cooling water to liquefy and then supplied to the evaporator again.

This absorption chiller is a product that mainly uses water as a refrigerant, and is environmentally non-polluting. In terms of energy used, heat energy is used as a driving source to prevent power concentration in the summer. It has the advantage of being able to drive safely.

1 and 2 are configuration diagrams showing the structure of a conventional absorption chiller. Referring to Figures 1 and 2, the conventional absorption chiller includes an evaporator 11, an absorber 12, and an evaporator 11. And a first shell 10 composed of a first eliminator 13 installed between the absorber 12 and the regenerator 21 positioned above the first shell 10 and the regenerator 21 It consists of a configuration including a second shell 20 composed of a condenser 22 positioned at the top and a second eliminator 23 provided on the side of the condenser 22.

In the absorption chiller composed of the first shell 10 and the second shell 20 as described above, the refrigerant line 33 through which the refrigerant 53 flows, the dilute solution line 31 and the agricultural solution line 32 through which the absorption liquid flows are provided. In this case, the refrigerant line 33 is connected from the condenser 22 to the evaporator 11, the rare solution line 31 is connected from the absorber 12 to the regenerator 21, and the agricultural solution line 32 is a regenerator. It is connected to the absorber 12 at (21).

In addition, a cooling water line 42 for moving cooling water supplied from the outside is connected to the absorber 12 and the condenser 22 in the order of the absorber 12 and the condenser 22, and the evaporator 11 has a cold water line 43 ) Is provided, and the regenerator 21 is provided with a heat source line 41 for discharging the heat source in the form of hot water or steam used to heat the absorbent liquid.

Looking at the driving of the absorption chiller configured as described above, first, in order to drive the chiller, a heat source and coolant must be supplied to the heat source line 41 and the coolant line 42, respectively.

Under these conditions, the dilute solution, which is an absorbent liquid located in the regenerator 21, is heated by a heat source (hot water or steam) supplied to the heat source line 41, and the heated dilute solution is separated by evaporation of the refrigerant 53 contained therein. As an agricultural solution 52, the agricultural solution 52 is supplied to the absorber 12 through the agricultural solution line 32, and the evaporated refrigerant 53 is supplied to the condenser 22.

In addition, in the condenser 22, a refrigerant in a gaseous state (hereinafter, referred to as'refrigerant vapor') is condensed by the cooling water supplied from the outside through the cooling water line 42 to become the refrigerant 53 in a liquid state again. In this way, the refrigerant 53 liquefied in the condenser 22 is supplied to the evaporator 11 through the refrigerant line 33 and is dispersed from the top of the evaporator 11 to the cold water line 43.

The refrigerant 53 scattered in the cold water line 43 absorbs the heat of vaporization from the cold water flowing through the cold water line 43 and evaporates, and the cold water deprived of heat by the refrigerant 53 reaches a lower temperature than when it flows into the evaporator 11. It is cooled and discharged. At this time, the refrigerant 53 that has been dispersed in the evaporator 11 but has not been evaporated is collected in the lower portion of the evaporator 11 and is supplied to the upper portion of the evaporator 11 by the refrigerant pump 33a to be dispersed.

In addition, the refrigerant vapor evaporated in the evaporator 11 is moved to the absorber 12, and since the absorber 12 has an agricultural solution line 32 connected thereto, the agricultural solution 52 supplied from the regenerator 21 is It is scattered from the top of the absorber 12 to the cooling water pipe. At this time, the agricultural solution 52 scattered inside the absorber 12 absorbs the refrigerant vapor, and in this process, the agricultural solution 52 becomes the rare solution 51, and the absorption heat in the process of absorbing the refrigerant vapor Will occur.

This absorption heat is supplied to the cooling water through the cooling water line 42 provided inside the absorber 12.

In this way, the dilute solution 51, which is an absorbent liquid in which the refrigerant 53 is mixed in the absorber 12, is pressurized by the dilute liquid pump 31a and supplied to the regenerator 21 through the dilute solution line 31, and the regenerator 21 In ), the dilute solution 51 is heated with external heat to separate the agricultural solution 52 and the refrigerant 53.

For reference, reference numeral 34 in the drawings denotes a heat exchanger for exchanging heat between the agricultural solution 52 passing through the agricultural solution line 32 and the rare solution 52 passing through the rare solution line 31.

Therefore, in a conventional absorption chiller, the absorbent liquid repeatedly circulates through the regenerator 21 and the absorber 12, and the refrigerant 53 passes the regenerator 21, the condenser 22, the evaporator 11 and the absorber 12. It has a structure that cools cold water while being repeatedly circulated and continuously operated.

However, in the conventional absorption chiller having the above configuration, a regenerator through which a heat source line for flowing a heat source flows in order to regenerate an absorbent liquid, that is, to regenerate a rare solution into an agricultural solution, and a refrigerant vapor by heat exchange with cooling water. Since the configuration of a condenser for condensing into a liquid refrigerant is essentially provided, there is a problem in that it is difficult to manufacture the facility because the facility is complicated.

In particular, conventional absorption chillers have to supply a high-temperature heat source to the regenerator in order to regenerate the absorbent liquid, so energy is excessively required to produce a high-temperature heat source, resulting in poor efficiency, and the cooling water dilutes the agricultural solution in the absorber. In addition to being supplied to regenerate as a solution, it must be supplied to heat exchange of refrigerant vapor into a liquid refrigerant in the condenser.The amount of cooling water supplied is inevitably increased.As the amount of water consumption increases due to the supply of cooling water, the efficiency is also good. There was a problem.

Korean Patent Registration No.0981672 (2010.09.06.)

The present invention was conceived in light of the above problems, and the technical problem to be solved by the present invention is a regenerator through which a heat source line for a heat source flows to regenerate an absorbent liquid, that is, a rare solution into an agricultural solution. Wow, by eliminating the configuration of the condenser for condensing the refrigerant vapor into a liquid refrigerant by heat exchange with the cooling water, the absorption liquid is regenerated, thereby simplifying the facility and using a non-heating regeneration process that is easy to manufacture. Is to provide.

In particular, the technical problem to be solved by the present invention is that by not using a high-temperature heat source to regenerate the absorbent liquid, a non-heating regeneration process that can improve efficiency by reducing energy consumption for producing a high-temperature heat source is used. It is to provide an absorption chiller.

In addition, another technical problem to be solved by the present invention is that by excluding the configuration of a condenser for exchanging refrigerant vapor with a liquid refrigerant, the supply amount of cooling water is reduced, and thus the consumption of water is reduced, thereby improving efficiency. It is to provide an absorption chiller using a non-heating regeneration process.

The problems of the present invention are not limited to the problems mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

An absorption chiller using a non-heating regeneration process according to an embodiment of the present invention for solving the above problem includes an evaporator and an absorber disposed to face each other with an eliminator therebetween; A membrane for separating the dilute solution into a refrigerant and an agricultural solution while passing the dilute solution converted by absorption of the refrigerant gas in the absorber; And an agricultural solution chamber receiving and storing the agricultural solution separated by the membrane, wherein the agricultural solution stored in the agricultural solution chamber is supplied to an absorber by a control signal to heat exchange with cooling water, and a refrigerant separated by the membrane Is supplied to the evaporator, and the refrigerant circulating in the evaporator performs heat exchange with cold water passing through the evaporator, so that the cold water is discharged at a temperature lower than a temperature when the cold water is introduced.

At this time, a dilute solution line equipped with a pressure pump is connected between the absorber and the membrane, and an agricultural solution dispersing nozzle for dispersing an agricultural solution is disposed above the absorber, and the agricultural solution dispersing nozzle and the agricultural solution chamber Is connected by a first line, which is one of the agricultural solution lines, and a first orifice and a first control valve opened and closed by a control signal may be installed on the first line.

In addition, the agricultural solution chamber and the rare solution line may be connected by a second line that is another one of the agricultural solution lines, and a second control valve that is opened and closed by a control signal may be installed on the second line.

In addition, a refrigerant recovery line for supplying the refrigerant separated by the membrane to the evaporator may be further included, and a second orifice may be installed in the refrigerant recovery line.

Meanwhile, a refrigerant line installed with a refrigerant pump is connected between the bottom and the upper portion of the evaporator, and a refrigerant dispersing nozzle for dispersing refrigerant is disposed at the upper part of the evaporator, and the refrigerant distributed through the refrigerant dispersing nozzle is transferred to the evaporator. It is scattered into the disposed cold water flow pipe, and heat exchange with cold water flowing through the cold water flow pipe can be achieved.

Other specific details of the present invention are included in the detailed description and drawings.

According to the absorption chiller using the non-heating regeneration process according to an embodiment of the present invention, a regenerator through which a heat source line for flowing a heat source flows in order to regenerate an absorbent liquid, that is, to regenerate a rare solution into an agricultural solution, and a refrigerant vapor with cooling water. Although the configuration of the condenser for condensing into a liquid refrigerant is excluded by heat exchange of the absorbent liquid, the absorption liquid is regenerated, thereby simplifying the facility, making it easier to manufacture, and thus, a useful effect of reducing manufacturing cost can be provided.

In particular, according to the absorption chiller using the non-heating regeneration process according to an embodiment of the present invention, by not using a high-temperature heat source to regenerate the absorbent liquid, energy consumption for producing a high-temperature heat source is reduced, thereby greatly improving efficiency. The effect of being able to be provided can also be provided.

In addition, according to the absorption chiller using the non-heating regeneration process according to an embodiment of the present invention, the configuration of a condenser for heat exchange of refrigerant vapor with a liquid refrigerant is also excluded, thereby reducing the supply of cooling water and eventually reducing the consumption of water. Also, the effect of maximizing efficiency can be provided.

The effects according to the present invention are not limited by the contents exemplified above, and more various effects are included in the present specification.

1 is a block diagram showing an absorption chiller according to the prior art.
Figure 2 is a configuration diagram for explaining the operation of the absorption chiller according to the prior art.
3 is a block diagram showing an absorption chiller using a non-heating regeneration process according to an embodiment of the present invention.

Advantages and features of the present invention, and a method of achieving them will be apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, only the present embodiments are intended to complete the disclosure of the present invention, and the general knowledge in the technical field to which the present invention pertains. It is provided to fully inform the scope of the invention to those who have it, and the invention is only defined by the scope of the claims. The same reference numerals refer to the same elements throughout the specification.

Thus, in some embodiments, well-known process steps, well-known structures, and well-known techniques have not been described in detail in order to avoid obscuring interpretation of the present invention.

The terms used in this specification are for describing exemplary embodiments and are not intended to limit the present invention. In this specification, the singular form also includes the plural form unless otherwise specified in the phrase. Comprises and/or comprising as used in the specification means not to exclude the presence or addition of one or more other components, steps and/or actions other than the mentioned components, steps and/or actions. Use as. And, "and/or" includes each and every combination of one or more of the recited items.

In addition, the embodiments described in the present specification will be described with reference to a perspective view, a cross-sectional view, a side view, and/or a schematic view, which are ideal exemplary views of the present invention. Accordingly, the shape of the exemplary diagram may be modified by manufacturing technology and/or tolerance. Accordingly, embodiments of the present invention are not limited to the specific form shown, but also include a change in form generated according to a manufacturing process. In addition, in each drawing shown in the exemplary embodiment of the present invention, each component may be somewhat enlarged or reduced in consideration of convenience of description.

Hereinafter, an absorption chiller using a non-heating regeneration process according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram showing an absorption chiller using a non-heating regeneration process according to an embodiment of the present invention.

As shown in FIG. 3, the absorption chiller 100 using the non-heating regeneration process according to the embodiment of the present invention includes an evaporator 110 and an absorber disposed opposite to each other with an eliminator 120 therebetween. 130).

In addition, the absorption chiller 100 using the non-heating regeneration process according to an embodiment of the present invention passes the dilute solution 132 converted by heat exchange with the cooling water in the absorber 130 while passing the dilute solution 132 as a refrigerant. (112) and a membrane 150 that is regenerated by separating it into an agricultural solution, and an agricultural solution chamber 160 that receives and stores the agricultural solution separated by the membrane 150. .

In addition, the absorption chiller 100 using the non-heating regeneration process according to an embodiment of the present invention includes a refrigerant line 114 and a refrigerant recovery line 152 through which the refrigerant 112 flows, and a dilute solution line through which the absorbent liquid flows. (134) and the agricultural solution lines 162 and 163 may be further included.

Here, the refrigerant line 114 is installed to connect the upper portion of the evaporator 110 from the bottom of the evaporator 110, and at this time, the refrigerant 112 collected at the bottom of the evaporator 110 is located at one side of the refrigerant line 114. A refrigerant pump 116 for pumping may be installed, and a refrigerant dispersing nozzle 118 for dispersing the refrigerant 112 may be installed at an upper end of the evaporator 110.

A cold water flow pipe 180 may be disposed below the refrigerant dispersion nozzle 118 of the evaporator 110, and accordingly, the cold water flowing through the inlet of the cold water flow pipe 180 is dispersed through the refrigerant dispersion nozzle 118. The heat exchange with the refrigerant 112 is performed to discharge cold water with a temperature lower than that of the cold water when it is introduced, which will be described in detail later.

In addition, the dilute solution line 134 is installed to connect the membrane 150 from the bottom of the absorber 130, and at this time, a dilute solution 132 collected at the bottom of the absorber 130 is placed on one side of the dilute solution line 134. A pressure pump 136 for pumping may be installed.

Therefore, by the operation of the pressure pump 136, the dilute solution 132 collected at the bottom of the absorber 130 moves to the membrane 150, and the membrane 150 passes through the introduced dilute solution 132 After separation into 112 and the agricultural solution, the refrigerant 112 is supplied to the evaporator 110 through the refrigerant recovery line 152, and the agricultural solution is supplied to the agricultural solution chamber 160.

The agricultural solution lines 162 and 163 include a first line 162 installed to connect the upper portion of the absorber 130 from the agricultural solution chamber 160, and a first line 162 connecting the agricultural solution chamber 160 and the dilute solution line 134. It may be divided into two lines 163, wherein an agricultural solution dispersing nozzle 168 for dispersing the agricultural solution may be installed at an upper end of the absorber 130 to which the first line 162 is connected.

At this time, when the agricultural solution flows from the agricultural solution chamber 160 to the agricultural solution dispersion nozzle 168 on the first line 162 of the agricultural solution line, a first orifice 164 for checking the flow rate of the agricultural solution Wow, a first control valve 166 for controlling the supply amount of the agricultural solution may be installed.

In addition, on the second line 163 of the agricultural solution line, a second control valve 165 that is opened and closed by a control signal to supply the agricultural solution from the agricultural solution chamber 160 to the rare solution line 134 may be installed. have.

A cooling water flow pipe 190 may be disposed below the agricultural solution dispersion nozzle 168 of the absorber 130, and accordingly, the cooling water flowing through the inlet of the cooling water flow pipe 190 is transmitted through the agricultural solution dispersion nozzle 168. The heat exchange with the dispersed agricultural solution is performed to discharge the cooling water with a temperature higher than the cooling water temperature when introduced, which will be described in detail later.

For reference, on the refrigerant recovery line 152 for supplying the refrigerant 112 separated from the membrane 150 to the evaporator 110, a second orifice may be installed to check the flow amount of the refrigerant 112 flowing. have.

The operation relationship of the absorption chiller 100 using a non-heating regeneration process that can be configured as described above will be described as follows.

First, the refrigerant 112 distributed through the refrigerant dispersing nozzle 118 located on the upper side of the evaporator 110 is distributed through the cold water flow pipe 180, and thus the refrigerant dispersed in the cold water flow pipe 180 112 absorbs the heat of vaporization from the cold water flowing through the cold water flow pipe 180 and evaporates, and the cold water deprived of heat by the refrigerant 112 is cooled to a lower temperature than when flowing into the evaporator 110 to be discharged. .

At this time, the refrigerant 112 scattered in the evaporator 110 but not evaporated is collected under the evaporator 110, and then the refrigerant in the upper part of the evaporator 110 by the refrigerant pump 116 installed on the refrigerant line 114. It is supplied to the dispersing nozzle 118 to continue dispersing.

Meanwhile, the refrigerant vapor evaporated by heat exchange with cold water in the evaporator 110 passes through the eliminator 120 and moves to the absorber 130, and the agricultural solution dispersion nozzle 168 is placed above the absorber 130. Through this, the agricultural solution is distributed to the cooling water flow pipe 190.

At this time, the agricultural solution dispersed through the agricultural solution dispersing nozzle 168 in the absorber 130 absorbs the refrigerant vapor supplied from the evaporator 110, and in this process, the agricultural solution is converted into a dilute solution 132. In this case, absorption heat is generated in the process of absorbing the refrigerant vapor by the agricultural solution.

Accordingly, the absorption heat generated at this time is supplied to the cooling water through the cooling water flow pipe 190 disposed inside the absorber 130 so that the cooling water is discharged at a temperature higher than the temperature when the cooling water is introduced.

In this way, the dilute solution 132 in which the refrigerant vapor is mixed in the absorber 130 is pressurized by the pressure pump 136 and supplied to the membrane 150 through the dilute solution line 134, and the membrane 150 is a refrigerant The refrigerant 112 is separated and regenerated as an agricultural solution while passing the dilute solution 132 mixed with (112), and then the refrigerant 112 is supplied to the evaporator 110 through the refrigerant recovery line 152, The solution is supplied to the agricultural solution chamber 160.

Therefore, after separation into the refrigerant 112 and the agricultural solution in the membrane 150, the refrigerant 112 supplied to the agricultural solution chamber 160 passes through the first line 162 forming the agricultural solution line by a control signal. It is dispersed through the agricultural solution dispersing nozzle 168 disposed in the absorber 130 through the absorber 130 to achieve heat exchange with the cooling water.

At this time, the first control valve 166 is blocked by the control signal, and the second control valve 165 is opened so that the agricultural solution supplied to the agricultural solution chamber 160 is a dilute solution through the second line 163. After being sent back to the line 134, a process of separating the refrigerant 112 from the membrane 150 may be performed.

That is, among the agricultural solutions in which the refrigerant 112 is separated by the membrane 150, the refrigerant 112 may be supplied to the agricultural solution chamber 160 in a state in which the refrigerant 112 is not completely separated, so that it is supplied to the agricultural solution chamber 160. The concentrated solution is sent back to the dilute solution line 134 and passes through the membrane 150 again, so that a process of completely separating the remaining refrigerant 112 may be further performed.

As described above, in the absorption chiller 100 using the non-heating regeneration process according to the embodiment of the present invention, the agricultural solution is converted into the dilute solution 132 by heat exchange with the cooling water in the absorber 130. , In order to regenerate the dilute solution 132 into an agricultural solution, a regenerator is not required as in the prior art. As a result of not having to use a high-temperature heat source to regenerate the absorbent solution, energy consumption for the production of a high-temperature heat source It is possible to maximize the efficiency by reducing.

That is, since the membrane 150 separates the dilute solution 132 into the agricultural solution and the refrigerant 112, it is not necessary to use a high-temperature heat source due to the need for a regenerator as in the prior art. It is possible to reduce energy consumption.

Accordingly, the configuration of the condenser for condensing the refrigerant vapor generated in the process of regenerating the absorbent liquid in the regenerator into the liquid refrigerant 112 as in the prior art is also excluded, so that the amount of supply of the cooling water is reduced and the consumption of water is reduced. The effect of maximizing efficiency can also be provided.

In particular, a regenerator through which a heat source line through which a heat source flows in order to regenerate the absorbent solution, that is, to regenerate the rare solution 132 into an agricultural solution, and the refrigerant vapor are condensed into the liquid refrigerant 112 by heat exchange with the cooling water. Since the configuration of the condenser for the purpose is rearranged, the facility is simplified and the manufacturing thereof is easy, thereby reducing the manufacturing cost.

For reference, the absorption chiller 100 using a non-heating regeneration process that can be configured as described above can be applied to a relatively medium/large capacity class, and in this case, its effect can be further maximized.

Those of ordinary skill in the art to which the present invention pertains will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, it should be understood that the embodiments described above are illustrative and non-limiting in all respects. The scope of the present invention is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention.

100: absorption chiller 110: evaporator
112: refrigerant 114: refrigerant line
116: refrigerant pump 118: refrigerant dispersion nozzle
120: eliminator 130: absorber
132: dilute solution 134: dilute solution line
136: pressure pump 150: membrane
152: refrigerant recovery line 154: second orifice
160: agricultural solution chamber 162: first line (agricultural solution line)
163: second line (agricultural solution line) 164: first orifice
165: second control valve 166: first control valve
168: agricultural solution dispersion nozzle 180: cold water flow pipe
190: cooling water flow pipe

Claims (5)

An evaporator and an absorber disposed to face each other with an eliminator therebetween;
A membrane for separating the dilute solution into a refrigerant and an agricultural solution while passing the dilute solution converted by absorption of the refrigerant gas in the absorber; And
It includes an agricultural solution chamber for receiving and storing the agricultural solution separated by the membrane,
The agricultural solution stored in the agricultural solution chamber is supplied to an absorber by a control signal to exchange heat with the cooling water,
The refrigerant separated by the membrane is supplied to the evaporator,
The refrigerant circulating in the evaporator performs heat exchange with cold water passing through the evaporator, and is discharged at a temperature lower than the temperature at which the cold water is introduced,
A dilute solution line equipped with a pressure pump is connected between the absorber and the membrane,
An agricultural solution dispersing nozzle for dispersing an agricultural solution is disposed on the upper part of the absorber, and the agricultural solution dispersing nozzle and the agricultural solution chamber are connected by a first line, which is one of the agricultural solution lines, and a first line is provided on the first line. 1 An absorption chiller using a non-heating regeneration process, characterized in that an orifice and a first control valve that is opened and closed by a control signal are installed.
delete The method of claim 1,
The agricultural solution chamber and the rare solution line are connected by a second line, which is another one of the agricultural solution lines, and a second control valve opened and closed by a control signal is installed on the second line. Absorption chiller using.
The method of claim 1,
An absorption refrigerator using a non-heating regeneration process, further comprising a refrigerant recovery line for supplying the refrigerant separated by the membrane to the evaporator, and wherein a second orifice is installed in the refrigerant recovery line.
The method of claim 1,
A refrigerant line in which a refrigerant pump is installed is connected between the bottom and the top of the evaporator,
A refrigerant dispersing nozzle for dispersing refrigerant is disposed above the evaporator,
The refrigerant dispersed through the refrigerant dispersing nozzle is distributed to a cold water flow pipe disposed in the evaporator, and heat exchange with cold water flowing through the cold water flow pipe.

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