KR100339399B1 - Absorption heat pump - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat pump, and more particularly, to an absorption heat pump configured to prevent a liquid refrigerant from stagnating inside the evaporator by introducing a refrigerant to an upper end of the evaporator.

To this end, the present invention is a regenerator having a heater for heating a refrigerant on one side, a condenser connected to the top of the regenerator through a rectifier to condense the refrigerant vapor, an absorber connected to the regenerator to absorb liquid refrigerant, A compressor for pressurizing the refrigerant discharged from the absorber to circulate back to the regenerator, a supercooler connected to the condenser and the absorber to evaporate the refrigerant in the form of a heat exchanger and a falling film; It is connected to be sucked by the subcooler and discharged to the subcooler again, there is provided an absorption heat pump having an evaporator for evaporating the refrigerant in the form of a heat exchange action and a falling film.

Description

Absorption heat pump

The present invention relates to an absorption type heat pump, and more particularly, to an improvement in the structure of a heat pump in order to prevent the liquid refrigerant from stagnating inside the evaporator and thus reducing the performance of the evaporator.

As shown in FIG. 1, a general absorption type heat pump includes a regenerator 1, a rectifier 2, a condenser 3, a supercooler 4, expansion valves 11 and 12, an evaporator 5, and a water cooling absorber ( 6), the solution cooling absorber (7), the refrigerant reservoir (9), the compressor (8), the heater (10) and the like.

Looking at the operation of the absorption heat pump as described above are as follows.

The low concentration vapor generated by heating by the heater 10 in the regenerator 1 is changed into a high concentration refrigerant while passing through the rectifier 2, and is cooled by the cooling water 13 in the condenser 3, Passing through the subcooler 4 becomes a low-temperature liquid refrigerant.

The liquid refrigerant is expanded with steam while passing through the expansion valve 11 and the evaporator 5.

In this case, the evaporator 5 generates heat exchange with the cooling water 15 to supply cooling cooling water 15, and the refrigerant in the vapor and liquid states is the supercooler 4, the water cooling absorber 6, Through the refrigerant storage tank (9), the compressor (8), the rectifier (2) and the solution cooling absorber (7) is introduced into the regenerator (1) again.

And, as shown in Figure 2 (a), the evaporator (5) is located below the subcooler (4), the liquid refrigerant cooled in the lower portion of the subcooler through the expansion valve 11 the lower portion of the evaporator It is configured to flow into.

On the other hand, the inside of the evaporator is composed of a plate heat exchanger.

Therefore, as shown in FIG. 2 (b), when the refrigerant evaporates in the evaporator and the volume of the vapor phase increases, the liquid refrigerant is drawn upward by the shear force of the gas-liquid interface on the surface of the plate 30. have.

However, in the above case, if the liquid refrigerant evaporates sufficiently inside the evaporator, the phenomenon that the liquid refrigerant is stagnated in the evaporator does not occur.

However, if the rate of cold air introduced into the evaporator and evaporated by the outside air temperature is insufficient, or only a component having a low boiling point is evaporated from the ammonia which is the refrigerant, a low concentration of ammonia solution is stagnated inside the evaporator 5 The bleeding 20 phenomenon occurs.

That is, when the rectification is insufficient in the rectifier and the low concentration of ammonia refrigerant flows into the condenser or the outside air temperature is very low, and the temperature of the cold water used for the heat exchange is low, the temperature of the liquid refrigerant is very low, so that the evaporator is properly evaporated. As a result, the liquid refrigerant is stagnated under the evaporator.

Therefore, the effective area in which heat transfer occurs in the evaporator due to the bleeding phenomenon is reduced, the performance of the evaporator is reduced due to the decrease in the amount of refrigerant evaporation, and the refrigerant may be concentrated in the evaporator, the refrigerant shortage may occur in some devices There was this.

On the other hand, when the bleeding occurs in the related art, by increasing the concentration of the remaining solution in the evaporator to all evaporate, by operating the device properly to supply a high concentration of ammonia solution to the evaporator, or to increase the cold water side temperature of the Low concentration of ammonia solution was evaporated.

Alternatively, the device was operated for a long time in the normal operation mode to increase the concentration of the stagnant solution to completely evaporate.

However, the above method requires a special mode of operation, and even if the device is operated for a long time in a bleeding state, normalization of the device may not be possible due to outdoor temperature or operating conditions of the device.

In addition, a method of periodically discharging liquid refrigerant by installing a valve in a pipe connected to the water cooling absorber at the bottom of the evaporator is used in a large system, but it has a difficulty in applying to a small device that is difficult to manage periodically.

The present invention has been made to solve the above problems, in order to prevent the refrigerant is stagnated in the evaporator, to change the configuration of the evaporator and the supercooler in the heat pump, and improve the internal structure of the evaporator and the supercooler For that purpose.

1 is a schematic view showing the configuration of a conventional absorption type heat pump.

Figure 2 (a) is a perspective view of the main portion showing the configuration of the evaporator and the subcooler of Figure 1;

Figure 2 (b) is a state diagram showing the flow of the refrigerant in each channel of the plate of the evaporator of FIG.

Figure 3 is a schematic diagram showing the configuration of the absorption heat pump according to the present invention.

4 is a perspective view illustrating main parts of the evaporator and the supercooler of FIG. 3.

5 is a state diagram showing the flow of the refrigerant in each channel of the plate of the evaporator of FIG.

6 is a cross-sectional view showing a side of the coupling state of the evaporator and the subcooler of FIG.

Description of the main parts of the drawings

200. Evaporator 202. Solution distributor

204.Plate 210.Expansion valve

220. Supercooler

To this end, the present invention is a regenerator having a heater for heating a refrigerant on one side, a condenser connected to the top of the regenerator through a rectifier to condense the refrigerant vapor, an absorber connected to the regenerator to absorb liquid refrigerant, A compressor for pressurizing the refrigerant discharged from the absorber to circulate back to the regenerator, a supercooler connected to the condenser and the absorber to evaporate the refrigerant in the form of a heat exchanger and a falling film; It is connected to be sucked by the subcooler and discharged to the subcooler again, there is provided an absorption heat pump having an evaporator for evaporating the refrigerant in the form of a heat exchange action and a falling film.

Hereinafter, a preferred embodiment of an absorption type heat pump according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a schematic view showing the configuration of the absorption type heat pump according to the present invention, Figure 4 is a perspective view of the main portion showing the configuration of the evaporator and the supercooler of Figure 3, Figure 5 is a channel of each of the evaporator of Figure 3 6 is a state diagram illustrating a flow of a refrigerant, and FIG. 6 is a cross-sectional view illustrating a coupling state of the evaporator and the subcooler of FIG.

As shown in FIG. 3, the regenerator 100 has an outlet at the top and a bottom thereof, and an inlet at the top thereof, and is connected to the rectifier 110 through the outlet of the top of the regenerator.

In addition, the condenser 120 and the subcooler 220 are connected along the refrigerant passage, and the condenser 120 is configured to transfer heat by inflow and outflow of coolant 121 from the outside.

In addition, a refrigerant passage is connected to the evaporator 200 through an expansion valve 210 at the lower end of the subcooler 220, and is connected to the subcooler through an upper end of the evaporator. It is configured to exchange heat with the cooling water 201 of.

Meanwhile, the subcooler is connected to the water cooling absorber 300 side, and is connected to the refrigerant storage tank 330 and the compressor 320 through a refrigerant passage connected to a lower end of the water cooling absorber, and the rectifier 110 And through the inside of the solution cooling absorber 310, it is connected to the inlet of the upper end of the regenerator (100).

On the other hand, the operation of the heater pump will be described as follows.

The refrigerant inside the regenerator 100 is heated by the heater 130 to generate a low concentration refrigerant vapor and a liquid refrigerant.

In this case, the low concentration refrigerant vapor is moved up to the rectifier 110 connected to the outlet of the top of the regenerator 100, the rectifier 110 transfers condensation heat by heat exchange with the refrigerant entering through the compressor 320 It turns into a high concentration refrigerant vapor.

Then, the liquid refrigerant is moved to the solution cooling absorber 310.

On the other hand, the high concentration of refrigerant vapor is delivered to the condenser 120, is converted into a high concentration liquid refrigerant by heat exchange with the cooling water 121 flowing therein, and is moved to the subcooler 220.

The subcooler 220 is configured to exchange heat with the low temperature refrigerant from the evaporator 200, thereby further cooling the high concentration liquid refrigerant.

In addition, the liquid refrigerant is passed through the expansion valve 210 to the evaporator 200 and heat exchanged with the fluid 201 flowing through the evaporator, the liquid refrigerant is boiling in two phases of gas and liquid The fluid 201 is cooled to become a low temperature fluid 201 required for cooling.

The refrigerant exiting the evaporator 200 flows back into the subcooler 220, heat exchanges in the subcooler, rises to a high temperature, and flows into a lower end of the water cooling absorber 300.

On the other hand, the above refrigerant is mixed with the high temperature liquid refrigerant introduced into the solution cooling absorber 310, in this case the absorption heat generated is absorbed and removed by the cooling water 301 flowing in the absorber.

After the process, the refrigerant is introduced into the regenerator 100 through a flow path provided in the rectifier 110 and the solution cooling absorber 310 through the refrigerant storage tank 330 and the compressor 320. After that, the process is repeated.

On the other hand, as shown in Figure 4, the evaporator 200 is located in the upper portion of the supercooler 220, it is provided so that the liquid refrigerant passing through the evaporator flows into the subcooler through the lower portion of the evaporator.

In addition, the evaporator 200 and the inside of the subcooler 220 is composed of a plate heat exchanger, the upper portion of the evaporator is provided with a solution distributor 202 for distributing the refrigerant to each channel of the plate heat exchanger do.

Meanwhile, as shown in FIG. 5, in the evaporator provided with the plate type heat exchanger, the liquid refrigerant flowing into the upper end of the evaporator through the subcooler evaporates while flowing down while forming a falling film on the plate surface 204. Will be.

In addition, the liquid refrigerant that does not evaporate in the evaporator is volatilized at the bottom of the evaporator, and naturally moves along the refrigerant passage connected to the subcooler located under the evaporator.

In this case, the vapor refrigerant is also mixed with the liquid refrigerant and moved, and in the subcooling, the liquid refrigerant is evaporated through the same process in the form of the falling liquid film, and then discharged through the cold air flow path under the subcooler. .

However, although the evaporator and the subcooler in the form of a falling liquid film are advantageous over the conventional method in terms of bleeding, a means for uniformly distributing the liquid refrigerant flowing into the evaporator to each channel of the plate is required.

Therefore, it is possible to uniformly distribute the refrigerant by providing a solution distributor such as a nozzle or a tube formed with pores.

On the other hand, as shown in Figure 6, since each channel of the plate of the evaporator 200 is manufactured integrally connected with each channel of the plate of the subcooler 220, the upper part of the evaporator from the lower part of the subcooler The refrigerant can flow down naturally.

Therefore, a solution distributor for distributing the refrigerant delivered from the evaporator is not necessary on the upper portion of the subcooler 220, and the evaporation effect of the refrigerant in the evaporator and the supercooler can be further increased.

In addition, even when not connected to a single refrigerant passage as in the prior art, the volume of the steam refrigerant in the mixed refrigerant of the liquid and vapor flowing into the upper portion of the supercooler is very large, so that a separate solution distributor in the subcooler Without this, it is possible to be distributed to each channel of the plate of the subcooler.

As described above, the present invention is configured so that the refrigerant flows from the upper side to the lower side in the evaporator and the subcooler, and the refrigerant is transferred from the lower side to the other engine, respectively, even when the liquid refrigerant does not partially evaporate. It does not remain in the evaporator and the supercooler and flows out to the absorber side.

Therefore, it is possible to eliminate the possibility of bleeding in the evaporator, it is possible to operate without the phenomenon that the liquid refrigerant is collected in the evaporator even under very low ambient temperature conditions.

Therefore, it is possible to prevent the performance degradation of the absorption heat pump, and the phenomenon that the liquid refrigerant collects in the evaporator disappears, so that the initial refrigerant filling amount can be reduced.

Claims (5)

A regenerator having a heater for heating a refrigerant, A condenser connected to the top of the regenerator through a rectifier to condense refrigerant vapor; An absorber connected to a bottom of the regenerator to absorb liquid refrigerant; A compressor for pressurizing the refrigerant discharged from the absorber to circulate back to the regenerator through a refrigerant storage tank; A supercooler connected to the condenser and the absorber to evaporate the refrigerant in the form of a heat exchanger and a falling film; And an evaporator connected to be sucked from the subcooler and discharged to the subcooler again to evaporate the refrigerant in the form of a heat exchanger and a falling film. The method of claim 1, The evaporator is located in the upper portion of the subcooler, the absorption heat pump, characterized in that the refrigerant is introduced into the upper portion of the subcooler from the bottom of the evaporator. The method of claim 1, The evaporator and the subcooler is an absorption heat pump, characterized in that provided with a plate type heat exchanger. The method of claim 1, Absorption heat pump, characterized in that the distribution channel for distributing the refrigerant uniformly to each plate on the top of the evaporator. The method according to claim 1 or 2, Absorption heat pump, characterized in that each channel of the plate of the evaporator is integrally provided with each channel of the plate of the subcooler.