KR200251512Y1 - Absorption Chiller - Google Patents

Abstract

The present invention is an evaporator (3) for cooling the cold water of the heat transfer tube group (6), an absorber (2) for absorbing the refrigerant vapor generated in the evaporator (3) to make a dilute solution, and a dilute solution of the absorber (2) In the absorption chiller comprising a high temperature regenerator and a low temperature regenerator to preheat the heat through the heat exchanger, and a condenser for condensing the refrigerant vapor separated through the low temperature regenerator and spraying the refrigerant vapor to the evaporator (3). The evaporator 3 is installed between the two absorbers 2 separated by the eliminator 4 in the c), and the heat transfer tube group 6 of the evaporator 3 is provided on both sides of the evaporator 3. It is characterized in that the part facing the emitter 4 is arranged in a sawtooth shape. Therefore, the flow resistance (pressure loss) of the steam in the evaporator 3 heat transfer pipe group 6 is reduced, and the refrigerant vapor can efficiently flow into the absorber 2 from the evaporator 3, so that the refrigerant in the absorber 2 is reduced. Absorption of the vapor is promoted, which can greatly improve the performance of the absorption refrigerator.

Description

Absorption chiller

The present invention relates to an absorption chiller, which is arranged in two absorbers and one evaporator separated by an eliminator in a shell, and the heat transfer tube group of the evaporator is arranged in a sawtooth shape to reduce the flow resistance of the vapor to evaporate and The present invention relates to an absorption chiller having a drastic improvement in absorption efficiency and a drastic improvement in freezing performance.

Generally, the absorption chiller is composed of an absorber, an evaporator, a condenser, a low temperature regenerator, a high temperature regenerator, a pump connecting the same, a heat exchanger, and the like, in which the absorber 2 'and the evaporator 3' are disposed adjacent to each other. The heat transfer tube group 6 'of the evaporator 3' also has an overall rectangular arrangement structure in which refrigerant vapor is difficult to flow.

Referring to FIG. 3 for the principle flow diagram of a conventional absorption refrigerator, water flows in the tube of the heat transfer tube group 6 'in the evaporator 3', and water is dispersed as a refrigerant outside the tube, By cooling the water in the tube to be supplied to the cooler or the like as cold water. The refrigerant vapor evaporated from the evaporator 3 'flows into the absorber 2' and is absorbed by the absorbing liquid scattered on the outer surface of the tube group 5 'in the absorber 2', and the absorber 2 'and the evaporator. 3 'is adjacent to the partition and eliminator 4 provided in the shell 1 inside. In the absorber 2 ', the absorbent solution supply pipe 7 and the plurality of absorption heat pipe groups 5' are arranged, and in the evaporator 3, the refrigerant supply pipe 8 and the plurality of evaporation heat pipe groups 6 'are disposed. have.

Cooling water is supplied into the tube of the insulator tube group 5 'of the absorber 2' side, and the heat of absorption in the absorber 2 'is removed. Absorption liquid absorbed the refrigerant vapor in the absorber (2 ') is reduced in concentration, the absorption power is weakened to become a rare solution, which is again preheated through a heat exchanger and sent to a high temperature regenerator and a low temperature regenerator to be concentrated by heating.

Among the components of the absorption refrigerator, it is the absorber 2 'and the evaporator 3' that are important to determine the performance. In order to improve the performance of the absorption refrigerator, as described above, the vapor pressure of the evaporation medium with respect to the evaporator 3'and the vapor pressure of the absorbent liquid (e.g., lithium bromide (LiBr) solution) in the absorber 2 ' It is necessary to increase the effective pressure difference. To do so, the flow resistance (pressure loss) of the vapor in the heat transfer tube groups 5 'and 6' of the absorber 2 'and the evaporator 3' is made small so that the evaporation in the absorber 2 'is reduced. It is necessary to increase the pressure difference that can be used for absorption.

However, as shown in FIG. 1, in the conventional absorption refrigerator, when the refrigerant vapor stays only in the shell 1, the pressure in the evaporator 3 'rises and the refrigerant does not evaporate, thus making it impossible to form cooling cold water. Therefore, it is necessary to absorb the refrigerant vapor efficiently in the absorber 2 'and to remove the refrigerant vapor in the shell 1.

In addition, as shown in FIG. 1, in the conventional absorption refrigerator, since the evaporator 3 'and the absorber 2' in the shell 1 each have one structure, the passage of steam is limited, and the evaporator ( The refrigerant vapor evaporated at the portion of the heat pipe group 6 'in the evaporator 3' located at a position far away from the absorber 2 'in 3') reaches the absorber 2 beyond the eliminator 4 The efficiency is lowered, and the absorber 2 'also has a lot of room for improvement due to the poor absorption efficiency at the portion of the heat pipe group 5' in the absorber 2 'that is far from the evaporator 3'. .

Therefore, the present invention has been devised to solve the above problems, and its purpose is to reduce the flow resistance of the vapor in the absorber and the evaporator to greatly improve the evaporation and absorption efficiency, thereby improving the freezing performance. It is an object of the present invention to provide an absorption refrigerator.

1 is a view showing the arrangement of the absorber and the evaporator of the conventional absorption refrigerator.

2 is a view showing the arrangement of the absorber and the evaporator of the absorption refrigerator according to the present invention.

3 is a conceptual diagram of an entire system of an absorption refrigerator.

* Explanation of symbols for main parts of the drawings

1: shell 2: absorber

3: evaporator 4: eliminator

5: Heat transfer tube group in absorber 6: Insulation tube group in evaporator

7: Absorbing liquid supply pipe 8: Refrigerant supply pipe

11: absorbent liquid 12: refrigerant

13: arrow indicating the flow of refrigerant vapor

The present invention for achieving the above object is an evaporator for cooling the cold water of the heat transfer tube group, an absorber for absorbing the refrigerant vapor generated in the evaporator to make a dilute solution, and after preheating the diluted total liquid of the absorber through a heat exchanger, respectively An absorption chiller comprising a receiving high temperature regenerator and a low temperature regenerator, and a condenser for condensing refrigerant vapor separated through the low temperature regenerator and injecting the vaporized vapor into the evaporator, wherein the absorber is separated between two absorbers separated by eliminators in a shell. An evaporator is installed in the evaporator, and the heat exchanger tube group of the evaporator is characterized in that the parts facing the eliminators on both sides of the evaporator are arranged in a sawtooth shape.

Hereinafter, the absorption refrigerator according to the present invention will be described with reference to FIG. 2.

2 is a view showing the arrangement of the absorber and the evaporator of the absorption refrigerator according to the present invention, the evaporator (3) between the two absorbers (2) divided by the eliminator (4) in the shell (1) The absorbing solution 11 of the two absorbers 2 is connected to the pipe before going to the absorbing liquid pump (9), the heat transfer tube group 6 of the evaporator (3) is elimine on both sides of the evaporator (3) The part corresponding to the eater 4 is serrated, and has taken the structure which left it blank and arrange | positioned as if missing. Reference numeral 10 is a refrigerant pump.

In the absorber 2, an absorbent liquid supply pipe 7 and a plurality of absorber heat pipe groups 5 are arranged, and in the evaporator 3, a refrigerant supply pipe 8 and a heat transfer pipe group 6 of the plurality of evaporators 3 are disposed. have.

As described above, the configuration of the present invention increases the area of the evaporator 3 in contact with the absorber 2, thereby increasing the absorption rate of the absorber 2.

Hereinafter, the operation of the absorption refrigerator of the present invention will be described.

The absorbent liquid 11 is supplied to each absorber 2 from the absorbent liquid supply pipe 7, and the refrigerant | coolant 12 is scattered from the refrigerant supply pipe 8 to the evaporator 3. The refrigerant 12 evaporates in the heat transfer tube 6 of the evaporator 3 to become refrigerant vapor (following arrow 13 indicating the flow of refrigerant vapor) and move to the adjacent absorber 2. However, the heat transfer tube group 6 of the evaporator 3 has a serrated arrangement so that a passage through which the refrigerant vapor can efficiently move to the absorber 2 can be ensured more efficiently than the conventional arrangement, and the shell 1 By eliminating the two eliminators (4) within the cavity), a large number of passages to the absorber (2) can be secured, and the absorber (2) can be efficiently reached beyond the eliminator (4).

As described above, the absorption chiller according to the present invention has a structure in which the absorber 2 and the evaporator 3 are alternately arranged, and the arrangement of the heat pipe groups 6 of the evaporator 3 is a sawtooth arrangement, thereby providing an evaporator 3. By reducing the flow resistance (pressure loss) of the steam in the heat transfer tube group 6, the refrigerant vapor can be efficiently introduced into the absorber 2 from the evaporator 3, so that the absorption of the refrigerant vapor in the absorber 2 is accelerated. Thus, the performance of the absorption refrigerator can be significantly improved.

Claims (1)

An evaporator (3) for cooling the cold water of the heat transfer tube group (6), an absorber (2) for absorbing the refrigerant vapor generated in the evaporator (3) to make a dilute solution, and a dilute solution of the absorber (2) for a heat exchanger. An absorption chiller comprising a high temperature regenerator and a low temperature regenerator which are respectively preheated through a preheater, and a condenser for condensing refrigerant vapor separated through the low temperature regenerator and spraying the evaporator 3 in the shell 1. An evaporator 3 is installed between the two absorbers 2 divided by the eliminator 4, and the heat transfer tube group 6 of the evaporator 3 includes the eliminators on both sides of the evaporator 3. Absorption freezer, characterized in that the portion facing the 4) is arranged in a sawtooth type.