KR19980034314A - Rectifier Structure of Ammonia Absorption System - Google Patents

Abstract

The present invention relates to the rectifier structure of the ammonia absorption system, in particular to improve the rectifier efficiency by changing the internal structure of the heat pipe of the rectifier,

The present invention is such that the heat solution flowing from the absorber heat exchanger heat exchange with the high temperature refrigerant vapor generated in the regenerator, and the steel solution flowing into the heat transfer tube to induce an annular flow (Annular, annular) flow An insertion rod inserted into the heat transfer tube, and a support for supporting the insertion rod so as to be concentric with the inner diameter of the heat transfer tube.

Description

Rectifier Structure of Ammonia Absorption System

Conventional ammonia absorption system, by applying the heat generated from the burner 11 as shown in the first diagram to evaporate ammonia, a refrigerant from a strong aqueous ammonia solution (hereinafter referred to as a strong solution) to obtain ammonia refrigerant vapor and at the same time some ammonia Regenerator 1 to produce an aqueous ammonia solution (hereinafter referred to as medicinal solution) having a weak concentration caused by evaporation, and condensed water evaporated together with the refrigerant vapor generated in the regenerator 1 to be rectified by a high concentration of ammonia refrigerant vapor. And a high concentration of ammonia refrigerant vapor sent from the rectifier 3 through the refrigerant vapor flow passage 15 to be cooled by an intermediate medium such as cooling water or brine to condense it into a liquid refrigerant. A condenser 4 and an evaporator 6 for evaporating again the liquid refrigerant condensed in the condenser 4 using cold water to form a refrigerant vapor; An expansion valve 17 for expanding the liquid refrigerant flowing into the evaporator 6 through the liquid refrigerant passage 16 from the accumulator 4, and the liquid refrigerant condensed in the condenser 4 and the vaporized liquid from the evaporator 6 Refrigerant heat exchanger (5) and the refrigerant vapor evaporated in the evaporator (6) is formed so that the refrigerant vapor heat exchange to absorb the medicinal solution sent from the regenerator (1) of the initial concentration of the original regenerator (1) Through the absorber (9) for making a strong solution, the solution pump (10) for pumping the strong solution generated in the absorber (9) to the rectifier (3), and the chemical solution flow path (12) in the regenerator (1) Expansion valve (13) for expanding the drug solution flowing into the absorber (9), and the absorber so that the heat solution flowing from the absorber (9) to the regenerator 1 is heat exchanged with the drug solution generated in the regenerator (1) The solution cooling absorber (8) formed in (9) and the strong solution passed through the solution cooling absorber (8) Analyzer (2) formed to flow into the vial (1) and the refrigerant vapor flowing from the evaporator (6) to the absorber (9) rises, the water formed so that the cooling water flows in the absorber (9) so that heat exchange takes place It consists of the cold absorber (7).

And the rectifier (3) is a steel solution inlet (3a) is introduced into the rectifier (3) through the pumping of the solution pump 10, the steel solution generated in the absorber (9) and the steel solution The liquid solution flowing through the inlet (3a) heat exchanger tube (3b) for heat exchange with the high-temperature refrigerant vapor generated in the regenerator (1), and the steel solution whose temperature flowing through the heat transfer tube (3b) is raised A steel liquid outlet 3c for discharging to the absorber 8 and a refrigerant vapor outlet 3d formed in the rectifier to discharge the high-purity refrigerant vapor generated through the above-described action to the condenser 4.

In the conventional ammonia absorption type system configured as described above, the steel solution in the regenerator 1 is heated by the burner 11, which is a combustion unit, to generate a refrigerant vapor and a medicinal solution, and the refrigerant vapor is introduced into the rectifier 3 while rising. In (9) is condensed into the refrigerant vapor of high concentration by condensing the water evaporated with the refrigerant vapor through heat exchange with the strong solution flowing into the rectifier (3) through the pumping of the solution pump (10).

The medicinal solution produced by the regenerator 1 has a higher specific gravity than the strong solution and sinks to the lower part of the regenerator 1, and the medicinal solution is caused by the pressure difference between the regenerator 1, which is a high pressure part, and the absorber 9, which is a low pressure part. After expanding in the expansion valve 10 is introduced into the absorber (9).

The high concentration refrigerant vapor rectified by the rectifier (3) is introduced into the condenser (4) condensed into the liquid refrigerant through the heat exchange with the cooling water is dropped into the condenser (4), the condensed liquid refrigerant is an expansion valve ( After passing through 10) is expanded, the evaporator 6 is introduced and the temperature is raised to the evaporator 6 so that the refrigerant is evaporated back into the refrigerant vapor through heat exchange with the cold water.

The refrigerant vapor evaporated in the evaporator 6 lowers the temperature of the liquid refrigerant close to the evaporation temperature in the evaporator 6 through heat exchange in the liquid refrigerant condensed in the condenser 4 and the refrigerant heat exchanger 5. By raising the temperature near the saturation temperature of the absorber (9) to accelerate the absorption phenomenon, and also evaporates a small amount of refrigerant that does not evaporate in the evaporator (6).

The refrigerant vapor evaporated in the evaporator (6) is introduced into the absorber (9) after heat exchange in the refrigerant heat exchanger (5), and the refrigerant vapor introduced into the absorber (9) is applied to the medicinal solution produced in the regenerator (1). Absorption heat generated at this time is generated as a strong solution of the initial concentration of the regenerator 1 as heat exchange is performed in the cooling water and the water cooling absorber 7.

At this time, the medicinal solution generated in the regenerator 1 is cooled while being dispersed and dropped on the surface of the heat exchange coil of the solution cooling absorber 8 in which the low temperature strong solution flows after flowing into the upper part of the absorber 9 to accelerate the absorption of the refrigerant vapor.

The steel solution generated in the absorber 9 flows into the rectifier 3 through the steel solution inlet 3a formed in the upper part of the rectifier 3 by pumping the solution pump 10, and to the rectifier 3. The introduced steel solution exchanges heat with the refrigerant vapor generated and risen from the regenerator 1 while flowing in the heat transfer pipe 3b, and the steel solution whose temperature is increased after the heat exchange is again absorbed through the steel solution outlet 3c. Is discharged to the solution cooling absorber (8) formed therein.

The steel solution discharged into the solution cooling absorber 8 flows inside the heat exchange coil to exchange heat with the high temperature chemical solution, and then the temperature is raised. The steel solution is supplied to the upper part of the analyzer. The analyzer 2 The steel solution supplied to) is introduced into the regenerator 1 to repeat the above operation sequentially.

The cooling water (or heating water) introduced into the water cooling absorber 7 is raised to a temperature after heat exchange and sent to the indoor unit for heating.

That is, during cooling, the cold water whose temperature has fallen from the evaporator 6 is sent to the indoor unit to perform cooling, and the cooling water that cools the condenser 4 and the absorber 9 is heated to the outdoor unit and cooled again.

On the contrary, in the case of heating, the condenser and the absorber go through the condenser and the heated water is sent to the indoor unit to perform the heating, and the cold water passed through the evaporator is sent to the outdoor unit.

The above operation is performed while continuously circulating while the system is in equilibrium.

However, the rectifier of the conventional ammonia absorption system performs heat exchange by directly contacting the outer surface of the heat transfer pipe through which the strong solution flows and the ammonia refrigerant vapor generated from the regenerator, which does not require the steel solution flowing into the heat transfer pipe (a certain distance from the center of the heat transfer pipe). Since it also flows into the internal heat transfer effect was reduced.

Therefore, in view of the above, the present invention inserts a rod having a predetermined radius inside the heat transfer tube of the ammonia absorption system rectifier to maintain the outer surface area of the rectifier and to maintain the flow of the steel solution flowing inside (Annular, annular) flow. The purpose of the present invention is to improve internal heat transfer rate and to obtain high purity ammonia vapor.

1 is a cycle diagram of a conventional ammonia absorption system.

2 is a rectifier longitudinal sectional view of a conventional ammonia absorption system.

3 is a rectifier of the ammonia absorption system of the present invention,

(A) is longitudinal sectional view of rectifier.

(B) is front view of part A seen from the steel liquid outlet side of (A).

(B) section B-B '

Explanation of symbols on the main parts of the drawings

101: rectifier 102: liquid solution inlet

103: heat pipe 104: steel liquid outlet

105: refrigerant vapor outlet 106: insertion rod

107: support

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram of the ammonia absorption system rectifier according to the present invention, the steel solution inlet 102 is introduced into the rectifier 101 through the pumping of the solution pump, the steel solution generated in the absorber, and the steel Heat solution tube 103 formed in the rectifier 101 to exchange heat with the high temperature refrigerant vapor generated in the regenerator, the steel solution introduced through the solution inlet 102, the heat solution is heat-exchanged through the heat transfer tube 103 to raise the temperature It consists of a strong liquid outlet 104 for discharging to the solution cooling absorber, and a refrigerant vapor outlet 105 for discharging the high-purity refrigerant vapor generated through the above-described action to the condenser.

The heat transfer tube 103 is inserted into the heat transfer tube 103 to improve internal heat transfer, and the insertion rod 106 to maintain the concentricity or eccentricity between the insertion rod 106 and the heat transfer tube 103. It is composed of a plurality of supports 107 for supporting both ends of the 106.

Referring to the operation of the present invention configured as described above is as follows.

First, the steel solution generated in the absorber is introduced into the rectifier 101 through the steel solution inlet 102 formed in the upper portion of the rectifier 101 by the pumping of the solution pump, and the steel solution introduced into the rectifier 101 is Heat exchanges with the refrigerant vapor generated and risen from the regenerator while flowing in the heat transfer tube 103, and the steel solution whose temperature rises through the heat exchange is discharged to the solution cooling absorber formed in the absorber through the steel solution outlet 104.

The refrigerant vapor generated from the regenerator is in direct contact with the outer surface of the heat transfer tube 103 to perform heat exchange, and through the heat exchange, high-purity refrigerant vapor is generated and sent to the condenser through the refrigerant vapor outlet 105.

At this time, the steel solution flowing into the heat transfer tube 103 is guided by an annular (Annular type) flow by an insertion rod 106 having a predetermined diameter inserted into the heat transfer tube 103.

The end of the insertion rod 106 is supported by the support 107 so as to maintain concentricity or eccentricity with the inner diameter of the heat transfer tube 103, and the inside of the heat transfer tube 103 through the annular (annular) flow. The internal heat transfer rate of the refrigerant growth period which is generated from the flowing strong solution and the regenerator is improved to obtain ammonia refrigerant vapor of higher purity.

As described above, the present invention maintains the outer surface area of the rectifier by concentrically or eccentrically inserting a rod having a constant diameter into the heat transfer tube of the rectifier. The internal heat transfer rate of the refrigerant increase period which is easily generated by the flow and regenerator flowing in the heat transfer pipe is easily induced by the flow, and the rectifier has the effect of obtaining a higher purity ammonia refrigerant vapor.

The present invention relates to an ammonia absorption system, and more particularly, to a rectifier structure of an ammonia absorption system that improves the rectifier efficiency by changing the internal structure of the heat pipe of the rectifier.

Claims (5)

The heat transfer tube through which the steel solution flows in the rectifier to exchange heat with the refrigerant vapor generated in the regenerator generated by the regenerator from the absorber, and the steel solution introduced into the heat transfer tube are induced by an annular (annular, annular) flow. And a support for supporting the insertion rod such that the insertion rod is inserted into the heat transfer tube so that the insertion rod is concentric with the inner diameter of the heat transfer tube. The method of claim 1, The insertion rod is a rectifier structure of the ammonia absorption system, characterized in that having a constant diameter. The method of claim 1, The insertion rod is a rectifier structure of the ammonia absorption system, characterized in that eccentrically inserted into the inner diameter of the heat transfer tube. The method of claim 1, The support is a rectifier structure of the ammonia absorption system, characterized in that provided to support both ends of the insertion rod. The method of claim 1, Rectifier structure of the ammonia absorption system, characterized in that the support is provided with a plurality.