KR100308381B1 - Solution Heat Exchanger of Absorption Chiller - Google Patents

Abstract

The present invention relates to a solution heat exchanger of the absorption chiller to improve the efficiency of the solution heat exchanger, and the present invention relates to a rare water inlet (220) and a low temperature regenerator connected to a solution pump (70) located below the absorber (10). 40 is provided with a solution solution outlet 220a connected to the farm, and the solution solution inlet 218 connected to the low temperature regenerator 40 and the farm solution outlet 218a for supplying the farm solution to the absorber 10 are integrally provided. In the solution heat exchanger of the absorption chiller including the housing 210, the housing 210 is separated into vertical and horizontal directions so that the inside of the housing 210 can be divided into a high temperature heat exchange space 216 and a low temperature heat exchange space 214. The first plate 230 is provided with a partition plate 212 and first and second pipes 232 and 234 through which a dilute solution and a concentrated solution are penetrated while partitioning one end of the partition plate 212. Even if it faces the one plate 230 First and second bypass pipes 236 and 238 for dividing the other end of the partition plate 212 to allow the dilute solution and the concentrated solution to flow between the two diagonally arranged heat exchange spaces 214 and 216, respectively. Partitioned by a second plate 237; The outer surface of the high temperature heat exchange space 216 is provided with a concentrate solution inlet 218 and a concentrate solution outlet 218a, respectively, and the outer surface of the low temperature heat exchange space 214 is a solution solution inlet 220 and the rare solution It is characterized in that the discharge port 220a is connected to each other.

Description

Solution Heat Exchanger in Absorption Chiller

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a urine solution heat exchanger of an absorption chiller, and more particularly, by dividing a solution heat exchanger supplying a heavy solution sprayed into an absorber into a plurality of tubes so that a rare solution and a concentrated solution flow, and changing the flow thereof. It relates to a solution heat exchanger of the absorption chiller to improve the efficiency of the.

In general, the air conditioner is to maintain the optimum temperature and humidity according to all weather conditions and indoor environments, and a humidifier to maintain proper humidity, including air conditioning and heating to cool or warm the room air. Ventilation equipment for discharging indoor air to the outside is included.

Such an air conditioner may be classified into various types according to a refrigerant to be used, and in particular, water is used as a refrigerant to absorb cold and hot water.

In absorption type cold and hot water machine using water as a refrigerant, lithium bromide (LiBr) (absorption solution) is mainly used as an absorbent, and water and lithium bromide solution are heated using steam or hot water.

With reference to the accompanying Figure 1 to help the understanding of the present invention will be briefly described a general absorption chiller.

1 is a schematic diagram showing the flow of a general absorption chiller.

As a general configuration of this absorption refrigerator, the rare solution conveyed by the suction force of the solution pump 70 is heated with the concentrated solution flowing from the low temperature regenerator 40, and the concentrated solution heated the rare solution is the solution pump 70 A small amount of rare solution discharged from The heat exchanger 50 and the evaporator 20 are provided.

Here, the absorber 10 is to absorb the latent heat of condensation and dilution generated by the vaporized vapor is absorbed by the absorbing solution.

The evaporator 20 discharges the first tube 80 through which cold water flows and the refrigerant accumulated in the drain 62 of the lower portion to the upper portion of the evaporator 20.

The second tube 90 through which the coolant in the absorber 10 flows is connected to the condenser 30, and the third tube 110 through which hot water or steam provided in the low temperature regenerator 40 flows. Is connected to the bypass pipe 100.

In addition, the solution heat exchanger 50 integrally forms the rare solution inlet port 54a and the rare solution outlet port 54b, the concentrated solution inlet port 52a, and the concentrated solution outlet port 52b on both sides of the first housing 52. A heat exchange pipe 54 is provided between the rare solution inlet port 54a and the rare solution outlet port 54b.

The absorption chiller having such a configuration is supplied with the power described above, and the refrigerant pump 60 and the solution pump 70 are driven, and the rated operation is performed after the startup operation time of about 20 to 30 minutes.

That is, water, which is a refrigerant, is sprayed to the evaporator 20 through a nozzle, and cold water flows in the first tube 80 inside the evaporator 20, so that the refrigerant is at a saturation temperature corresponding to the pressure. Boil takes the heat from the cold water and evaporates it, so the cold water is cooled and supplied to the place where it is needed for cooling.

At this time, the vapor evaporated in the absorber 10 is absorbed by the absorbent solution (lithium bromide) as an absorbent, and latent heat of condensation is generated in the process of being absorbed.

In addition, the absorbing solution absorbs moisture to lower its concentration and generates dilution heat.

This dilution heat is removed by the second tube 90 installed in the absorber 10 through which the coolant flows.

On the other hand, the absorbing solution absorbed by the water is passed through the heat exchange pipe 54 in the solution heat exchanger 50 by the solution pump 70 installed in the absorber 10, the temperature is increased, In this state, it is supplied to the low temperature regenerator 40.

The absorbent solution supplied to the low temperature regenerator 40 is converted into a concentrated solution and then heat exchanged with the rare solution while moving through the concentrated solution inlet port 52a and the concentrated solution outlet port 52b of the solution heat exchanger 50. Some rare solution and diluted concentrate are sprayed into the absorber 10.

Meanwhile, the refrigerant vapor evaporated in the low temperature regenerator 40 is supplied to the condenser 30, cooled and condensed by the cooling water absorbing dilution heat in the absorber 10, and is supplied to the evaporator 20 in a liquefied state.

The low temperature regenerator 40 controls the solution pump 70 according to the solution level by a controller (not shown) to adjust the absorbing solution.

However, the rare solution from the absorber 10 is introduced into the heat exchange pipe 54 in the solution heat exchanger 50 by the solution pump 70, and the concentrated solution from the low temperature regenerator 40 is transferred to the solution heat exchanger ( 50) The heat exchange is introduced as it enters, but in order to achieve sufficient heat exchange, the solution cost increases due to the size of the solution heat exchanger 50 being increased.

In addition, when the solution heat exchanger 50 is made small in order to reduce the manufacturing cost, there is a problem in that the operating cost is high due to the increased consumption of the heating source in the regenerator.

Accordingly, the present invention has been made to solve such a problem, divided into a plurality of spaces so that the rare solution and the concentrated solution flows in the solution heat exchanger, and the contact area for indirect heat exchange of the rare solution and the concentrated solution It is an object of the present invention to provide a solution heat exchanger of an absorption chiller adapted to improve the efficiency of the solution heat exchanger by changing the flow to be wider.

1 is a schematic view showing the flow of a typical absorption chiller.

2 is a cross-sectional view showing the inside of the heat exchanger of the absorption chiller according to the present invention.

3 is an internal configuration of the solution heat exchanger of the absorption chiller according to the present invention.

<Description of the symbols for the main parts of the drawings>

210: housing 212: partition plate

216: high temperature heat exchange space 214: low temperature heat exchange space

218: agricultural solution inlet 218a: agricultural solution outlet

220: solution solution inlet 220a: solution solution outlet

230: First plate 232,234: First and second pipe

236,238: 1st and 2nd bypass piping

The present invention for achieving this has a solution solution inlet connected to the solution pump located in the lower part of the absorber and a solution solution outlet connected to the low temperature regenerator, and a farm solution discharge port for supplying the farm solution to the absorber solution inlet and absorber connected to the low temperature regenerator. In the solution heat exchanger of the absorption chiller comprising a housing integrally provided, the partition plate for partitioning the inside of the housing to the left and right up and down so that the inside of the housing is separated into a high temperature heat exchange space and a low temperature heat exchange space, and a first side on one side of the partition plate. And a first plate having two pipes and a second plate having first and second bypass pipes at the other end of the partition plate so as to face the first plate, wherein the high temperature heat exchange space includes a concentrated solution inlet and a concentrated solution. Each outlet is connected to each other, and the low temperature heat exchange space includes a rare solution inlet and a rare solution. It is achieved to provide a solution heat exchanger of the absorption chiller, characterized in that each outlet is connected to each other.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

Figure 2 is a cross-sectional view showing the inside of the solution heat exchanger of the absorption chiller according to the present invention, Figure 3 is an internal configuration of the solution heat exchanger of the absorption chiller according to the present invention.

Prior to explaining the present embodiment, the basic configuration of the absorption type refrigerator according to the present invention is the same as in the prior art, and the absorption type refrigerator according to the present invention will be described in connection with the related art as follows.

That is, the absorption chiller heats the rare solution conveyed by the suction force of the solution pump 70 to the concentrated solution flowing from the low temperature regenerator 40, and a small amount of the concentrated solution heated from the rare solution is discharged from the solution pump 70. It is provided with a solution heat exchanger (50) and an evaporator (20) to be sprayed into the absorber (10) through a nozzle in a diluted state with a dilute solution.

Here, the solution heat exchanger 50 integrally forms the rare solution inlet 54a and the rare solution discharge port 54b and the concentrated solution inlet 52a and the concentrated solution discharge port 52b on both sides of the first housing 52. Then, a heat exchange pipe 54 is provided between the rare solution inlet port 54a and the rare solution outlet port 54b.

In the absorption chiller having such a configuration, the absorbing solution that absorbs and dilutes water passes through the heat exchange pipe 54 in the solution heat exchanger 50 by a solution pump 70 installed under the absorber 10, The temperature rises and is supplied to the low temperature regenerator 40 in this state.

The absorbent solution supplied to the low temperature regenerator 40 is converted into a concentrated absorbent solution and then heat-exchanged with the rare solution while moving through the concentrated solution outlet 52b through the concentrated solution inlet port 52a of the solution heat exchanger 50. This is done, and some dilute solution and diluted concentrate are sprayed into absorber 10.

As described above, the present invention prevents the efficiency from being lowered in the process of performing heat exchange by the concentrated solution introduced from the low temperature regenerator 40 to the rare solution flowing in the heat exchange pipe 54 of the solution heat exchanger 50. The structure of the first housing 52 of the conventional solution heat exchanger 50 is changed.

That is, as shown in Figures 2 and 3, the housing 210 constituting the solution heat exchanger 200 according to the present invention is divided into a high temperature heat exchange space 216 and a low temperature heat exchange space 214, In addition, the rare heat and the concentrated solution passes through each of the two heat exchange spaces, so that the indirect heat exchange with each other is more actively performed.

In other words, the inside of the housing 210 of the solution heat exchanger 200 may partition the housing 210 up, down, left, and right so as to be divided into a high temperature heat exchange space 216 and a low temperature heat exchange space 214. And a first plate 230 having first and second pipes 232 and 234 through which the dilute solution and the concentrated solution penetrate while partitioning one end of the partition plate 212, and the first plate 230. First and second bypass pipes 236 and 238 for dividing the other end portion of the partition plate 212 so as to allow the concentrate and the concentrate to flow between the same two heat exchange spaces 214 and 216 disposed diagonally. It is partitioned by the 2nd plate 237 made.

Here, the outside of the low-temperature heat exchange space 214 of the housing 210 is provided with a rare solution inlet 220 and a rare solution discharge port 220a for introducing and discharging the rare solution, and the high temperature of the housing 210. Outside the heat exchange space 216, a concentrated solution inlet 218 and a concentrated solution outlet 218a for introducing and discharging the concentrated solution are provided.

The first plate 230 is provided such that the first and second pipes 232 and 234 are symmetric such that the concentrated solution and the rare solution flow into the high temperature heat exchange space 216 and the low temperature heat exchange space 214.

The first and second bypass pipes 236 and 238 are fixed to intersect the ends of the partition plate 212.

As described above, the rare solution discharged from the solution pump 70 includes a rare solution inlet 220 provided outside the housing 210 and a first pipe 232 provided below the first plate 230. It is introduced into the low temperature heat exchange space 214 through.

The rare solution introduced into the low temperature heat exchange space 214 is sent to the low temperature regenerator 40 through the low temperature heat exchange space 214 and the solution discharge port 220a positioned diagonally upward through the second bypass pipe 238. You lose.

Then, the concentrated solution of the low temperature regenerator 40 flows into the high temperature heat exchange space 216 through the second solution 234 of the farm solution inlet 218 and the first plate 230, and is provided at the end thereof. It flows into the high temperature heat exchange space 216 formed in the diagonal direction via the first bypass pipe 236.

The concentrated solution introduced into the high temperature heat exchange space 216 passes through the concentrated solution outlet 218a and is sprayed onto the absorber 10.

As a result, sufficient concentration of heat exchange is achieved through indirect heat exchange through a large area between the agricultural solution supplied from the low temperature regenerator 40 and the rare solution supplied to the solution pump 70.

As described above, in the present invention, the concentrated solution flowing from the low temperature regenerator and the rare solution discharged from the solution pump change the direction of the flow in the housing so that sufficient heat exchange is performed between the concentrated solution and the rare solution, There is an advantage to reduce the cost of manufacturing the heat exchanger.

Claims (1)

A solution solution inlet 220 connected to the solution pump 70 located below the absorber 10 and a solution solution outlet 220a connected to the low temperature regenerator 40 are provided, and a farm solution inlet connected to the low temperature regenerator 40 is provided. In the solution heat exchanger of the absorption chiller comprising a housing (210) and integrally provided with a farm solution discharge port (218a) for supplying the farm solution to the absorber 10, the inside of the housing 210 is a high temperature heat exchange space Partition plate 212 that separates the housing 210 vertically and horizontally so that it can be divided into 216 and the low temperature heat exchange space 214, and one side end of the partition plate 212, while the rare and the liquid solution The first plate 230 having the first and second pipes 232 and 234 introduced therethrough, and the same end disposed in the diagonal direction while partitioning the other end of the partition plate 212 so as to face the first plate 230. Between two heat exchange spaces (214, 216) Partitioned by a second plate 237 having first and second bypass pipes 236 and 238 for allowing the dilute solution and the concentrated solution to flow respectively; A concentrated solution inlet 218 and a concentrated solution outlet 218a are connected to the outer side of the high temperature heat exchange space 216, and a rare solution inlet 220 and a rare solution are provided on the outer side of the low temperature heat exchange space 214. Solution heat exchanger of the absorption chiller, characterized in that the discharge port 220a is connected to each other.