KR19990007793A - Absorption chiller - Google Patents

Abstract

In an absorption chiller whose main components are an evaporator, an absorber, a regenerator, a solution heat exchanger, and a condenser, the refrigerant condensation temperature generated by the regenerator before the condensation temperature is higher than the absorption temperature is supplied to the solution heat exchanger. Preheat by

Description

Absorption chiller

In general, absorption chillers have different temperature levels in the absorption process and the regeneration process, so that a low concentration refrigerant absorption solution (hereinafter referred to as a concentrated solution) and a low concentration refrigerant absorption solution (hereinafter referred to as a rare solution) in the heat exchanger are less. Heat exchange is carried out to recover the heat required for preheating the rare solution from the concentrated solution.

However, since the rare solution absorbs water in the absorber and the concentrated solution regenerated in the regenerator releases water when it is regenerated, the concentrated solution, which is a heat source, has a lower flow rate than the rare solution. In addition, the concentrated solution has a smaller specific heat than the rare solution. For this reason, the temperature rise of the rare solution becomes smaller than the temperature drop of the agricultural solution.

Therefore, the rare solution can only recover heat to a temperature lower than the regeneration start temperature. This means that only a part of the preheating of the rare solution is carried out in the heat exchanger, so that the preheating portion required for raising the temperature from the heat exchanger outlet temperature to the regeneration start temperature in the regenerator and for regeneration (concentration) Need heat Therefore, much heat source water is consumed by that much, and the performance coefficient of an absorption refrigerator is falling.

The present invention is an absorption chiller, more specifically, water or ammonia as a refrigerant, and lithium embrittlement or water as an absorbent, evaporator, absorber, heat exchanger, regenerator, condenser and the like as the main components. It relates to an absorption refrigerator.

1 is a schematic view of one embodiment of an absorption refrigerator according to the present invention.

FIG. 2 is a cycle diagram of the absorption refrigerator of FIG. 1. FIG.

3 is a schematic view of a conventional single-effect absorption chiller.

4 is a cycle diagram of the absorption refrigerator of FIG. 3.

Disclosure of the Invention

SUMMARY OF THE INVENTION The present invention has been made to solve such a conventional problem, and an object thereof is to provide an absorption refrigerator capable of reducing the heating amount in a regenerator and improving the coefficient of performance.

In order to achieve the above object, the absorption chiller of the present invention is an evaporator, an absorber, an absorption chiller comprising a solution heat exchanger and a concentrator as a main component of heat exchanger between the concentrated solution regenerated in the regenerator and the rare solution produced in the absorber, The temperature is higher than the absorption temperature, and the preheated solution is preheated by the refrigerant vapor generated in the regenerator before supplying the rare solution sent from the absorber to the solution heat exchanger.

The present invention sets the regeneration and condensation pressure higher than the conventional regeneration and condensation pressure to make the condensation temperature higher than the absorber outlet temperature and the condensation temperature of the refrigerant higher than the absorber outlet temperature of the rare solution. Thereby, the amount of heat of condensation of the refrigerant can be used for preheating the rare solution. In this case, of course, the regeneration pressure coincides with the condensation pressure, so that the regeneration temperature is higher than the conventional one.

The condensation pressure of the refrigerant is mainly dependent on the cooling temperature. Therefore, raising the condensation pressure of the refrigerant and setting the condensation temperature at an appropriate temperature for preheating the rare solution only requires using the rare solution for condensation of the refrigerant in the condenser. Is achieved. That is, the refrigerant vapor is cooled by the rare solution sent from the absorber instead of the cooling water of the conventional condenser. In this way, the latent heat of condensation can be used for preheating the rare solution.

Moreover, the rise of the regeneration temperature inevitably requires the rise of the heat source temperature, but there is no problem because the heat source temperature is high in the case of gas dust. In addition to gas, kerosene, steam and hot water may be used.

Therefore, the present invention preheats the rare solution using the condensate of the refrigerant in the condenser, in addition to the agricultural solution conventionally used as the heat source of the rare solution. Thus, the preheating temperature of the rare solution increases and the amount of heating in the regenerator decreases. The coefficient of performance of the absorption chiller rises.

Best Mode for Carrying Out the Invention

1 is a schematic view of an embodiment in which the present invention is applied to a single-effect absorption chiller using a LiBr solution, and FIG. 2 is a cycle diagram (duration diagram) for FIG. 1, wherein ξ is embrittlement that is a refrigerant absorption solution. The concentration of the lithium aqueous solution is shown. For example, ξ ₀ indicates the concentration of the brittle lithium aqueous solution at 0%, that is, the saturated state of pure water. ξ ₁ represents a state where the concentration of the lithium embrittlement aqueous solution is 55% (hereinafter referred to as rare solution), and ξ ₂ is a concentration of 60% (hereinafter referred to as a concentrated solution).

As shown in FIG. 1, the water 12 as the refrigerant evaporates by exchanging heat with the cooling water 13 supplied to the evaporator 21 from the heat transfer part 211 of the evaporator 21. The evaporated steam ① 'is supplied to the absorber 22 through the passage 31. The cold water 13 is cooled by the heat exchanger, and is sent out as the cold water 14 to be used.

In the absorber 22, the concentrated solution ⑧ flows on the surface of the heat transfer part 211. This concentrated solution ⑧ absorbs the steam ① 'generated in the evaporator 21, and the concentration of the solution decreases to form a rare solution ②. At this time, the coolant 15 supplied to the heat transfer part 211 of the absorber 22 is controlled so that the rare solution ② becomes below a predetermined temperature (saturation temperature T ₂ ). The cooling water 15 rises in temperature by a heat exchanger, and refluxs to a cooling tower (not shown) or the like as the cooling water 16.

Then, the rare solution (2), which is added to the bottom of the absorber (22), is sent out by the solution pump (25) and preheated between the heat transfer part (242) and the solution heat exchanger (27) of the condenser (24), respectively. Is sent to the player (23). This rare solution (2) is heated and boiled by the heat source water (30) flowing through the tube of the heat transfer section (231) of the regenerator 23, and the water (refrigerant) in the solution evaporates. The heat source water 30 becomes the hot water 31 while passing through the heat transfer pipe 231 of the regenerator 23, and is refluxed in a water heater (not shown) or the like.

The steam ④ ′ generated by the regenerator 23 flows into the condenser 24 through the passage 32 and condenses by heat exchange with the rare solution ② flowing through the tube of the heat transfer part 242 of the condenser 24. (5) and returns to the evaporator 21 via the expansion valve 20.

As described above, in the present invention, the regeneration and condensation pressure P ₄ is set high so that the condensation temperature is higher than the absorption temperature, and the condensation temperature T ₅ of the refrigerant is higher than the absorption port outlet temperature T ₂ of the rare solution. Therefore, the heat of condensation of the refrigerant can be used for preheating the rare solution.

That is, since the rare solution ② sent out from the absorber 22 is preheated in two stages by the heat transfer part 242 and the solution heat exchanger 27 of the condenser 24, as shown in FIG. The liquid temperature T ₇ of the outlet portion ⑦ of 27) rises to approach the regeneration initial temperature T ₈ of the rare solution ②, thereby reducing the heat consumption of the heat source water 30 in the absorber 22.

In addition, the conventional single-effect absorption chiller is configured to directly transfer the rare solution (2) in the absorber (22) to the regenerator (23) via the solution heat exchanger (27), and to the heat transfer portion (241) provided in the condenser (24). The point of supplying the cooling water 17 from the outside only differs, and the other points are not different from the single-effect absorption chiller of the present invention, and detailed description thereof will be omitted. In addition, the same equipment was given the same code | symbol as the single-effect absorption chiller of this invention.

Conventional single-effect absorption freezer as shown in Figure 3, the rare solution ② is heat-exchanged with the concentrated solution ④ in the solution heat exchanger (27) is heated from 36 ℃ to 55 ℃, but preheating to the regeneration start temperature 81 ℃ (temperature Rise 26 ° C.) also needs to be performed in the regenerator 23.

In the present invention, as shown in Fig. 1, the rare solution ② is led to the heat transfer part 242 of the condenser 24, and the preheating of the first stage is performed by the latent heat of the regenerated steam generated by the regenerator 23. Therefore, the temperature of the rare solution ② fed into the solution heat exchanger 27 rises from the original temperature 36 degreeC to 44 degreeC of the rare solution ②.

Therefore, the rare solution ② rises to 78 ° C at the outlet ⑦ of the solution heat exchanger 27, and it can be seen that it is very close to the regeneration start temperature 81 ° C compared with the conventional single-effect absorption refrigerator. . Therefore, the amount of heating required for preheating (temperature rise 3 ° C.) of the dilute solution ② in the regenerator 23 is greatly reduced.

As a result, although the heat input of the regenerator 23 is not shown, in this figure, the flow volume of the heat source water was reduced by about 28% compared with the past. In addition, the grade coefficient of the conventional single-effect absorption refrigerator shown in FIG. 3 is 0.65, and the grade coefficient of the single-effect absorption refrigerator of this invention shown in FIG. 1 is 0.83.

In Fig. 1,? Denotes a submerged liquid water under the evaporator 21, and 71 denotes an outlet portion of the heat transfer part 242 of the condenser 24. In addition, in FIG. 3, 18 has shown the cooling water sent from the heat transfer part 241 of the silver storage machine 24. As shown in FIG.

Absorption refrigerators using water as a refrigerant and lithium embrittlement as absorbers are not the only single-use type shown in this figure. There is a dual effect type that directs the steam generated in the regenerator to the second regenerator. Since the dual-effect type (not shown) guides the steam generated in the high-pressure regenerator to the low-pressure regenerator to be a heat source of the low-pressure regenerator, heat input in the high-pressure regenerator is approximately twice as effective as the single-use type. As a result, the grade factor is doubled.

However, as in the single-effect type, since the heat amount for preheating the rare solution in the heat exchanger is insufficient, the ratio equivalent to the preheating content of the rare solution in the heat input amount in the high-pressure regenerator cannot be ignored.

Therefore, if the preliminary solution of the first stage is preheated by the heat of condensation of steam generated in the low pressure regenerator, and then sent to the heat exchanger for low pressure solution, the application is basically similar to that of the present invention. Omit the description.

In the above description, the case where water is used as the refrigerant and lithium embrittlement is used as the absorbent is described. However, in addition to LiBr, the absorbent of the absorption refrigerator using water as the refrigerant is LiI, LiCl, LiNO ₃ , KBr, NaBr, CaCl ₂ , ZnCl. ₂ , ZnBr ₂ and mixtures thereof. The single component of LiBr is widely used because of its excellent performance, such as low corrosiveness and high crystallization concentration.

Moreover, in the absorption refrigerator which uses ammonia as a refrigerant and water as an absorbent, there exist more components, such as a rectifier and a deflector. However, in the heat cycle (on the During diagram), the preheating of the solution sent to the regenerator in the heat exchanger is not sufficient, and the amount of heating in the regenerator increases, leading to a decrease in the coefficient of performance. It is the same as the absorption refrigerator used.

Therefore, the temperature and pressure required for regeneration and condensation are set so that the condensation temperature of the ammonia vapor sent out from the regenerator is higher than the absorption temperature, and the preheating of the solution by the heat of condensation reduces the heating amount of the regenerator, resulting in a coefficient of performance. Can be raised. In this regard, it is the same as the absorption refrigerator using water and lithium embrittlement.

In addition, the refrigerating device is used for cooling (or cooling) purposes, but the heat source (cooling water) and heat output (cold water) are reversed by the same principle, and the heat input of the evaporator is used as the heat source, and the heat of cooling of the absorber is heat. By output, it can be used also for heating (or heating) as a heat pump.

Therefore, since the present invention is a technique that holds for both the absorption chiller and the absorption heat pump, the scope of the present invention also extends to the heat pump.

Claims (2)

Evaporator, absorber, regenerator, solution heat exchanger and condenser whose main components are heat exchangers between the concentrated solution regenerated in the regenerator and the rare solution produced in the absorber, wherein the condensation temperature is higher than the absorption temperature, and is discharged from the absorber. Absorption chiller, characterized in that preheating by the refrigerant vapor generated in the regenerator before supplying the rare solution to the solution heat exchanger. The method of claim 1, An absorption chiller comprising a heat transfer part for condensing refrigerant vapor sent from a regenerator to a condenser by a rare solution sent from an absorber.