KR100304019B1 - Dual-effect Absorption Chiller - Google Patents

Abstract

The dual-effect absorption chiller is equipped with a high temperature regenerator, a low temperature regenerator, a condenser, an evaporator, an absorber, a low temperature heat exchanger, and a high temperature heat exchanger, and uses an aqueous solution of an absorber and water, which is a refrigerant, and converts the liquid refrigerant in the evaporator into a low temperature heat exchanger. The supply passage which supplies in the flow path of the high concentration absorbent aqueous solution of this is provided, and the valve is provided in the supply passage. A supply passage for supplying the low concentration absorbent aqueous solution in the absorber into the flow path of the high concentration absorbent aqueous solution of the low temperature heat exchanger is provided, and a valve is provided in the supply passage.

Description

Dual Effect Absorption Chiller

1 is a schematic configuration diagram showing an embodiment of the present invention,

2 is a schematic configuration diagram showing another embodiment of the present invention,

3 is an enlarged view showing a part of the on / off valve of FIG.

4 is an enlarged view of the corresponding on / off valve of FIG. 3 showing a state different from that of FIG.

FIG. 5 is an enlarged view of the on / off valve corresponding to FIG. 3 showing a modification of the on / off valve of the dual-effect absorption cold / hot water machine shown in FIG.

6 is an enlarged view of the on / off valve corresponding to FIG.

7 is a schematic diagram showing another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: heating burner 2: high temperature regenerator

3: separator 4: low temperature regenerator

5: condenser 6: evaporator

7: absorber 8: low temperature heat exchanger

9: high temperature heat exchanger 11: heater

The present invention relates to a double effect absorption type refrigerating machine sealed inside a lithium bromide solution composed of, for example, water as a refrigerant and lithium bromide as an absorbent.

As a dual-effect absorption chiller of this kind, a conventional high temperature regenerator, a low temperature generator, a condenser, an evaporator, an absorber, a low temperature heat exchanger, a high temperature heat exchanger, a solution pump which sends a lithium bromide aqueous solution from the absorber to the high temperature generator and the water in the evaporator are again It is widely known to have a refrigerant circulation pump sprayed onto a heat transfer tube of an evaporator and to be used in a completely sealed vacuum state.

In the dual-effect absorption chiller, the lithium bromide aqueous solution may have a high concentration (63-64 wt%) and a high temperature (150-170 ° C.) during cold water production. As the concentration and temperature of the lithium bromide aqueous solution increase, non-condensable gas is more likely to be generated by chemical reaction with the metal, and the generated non-condensable gas is collected around the heat transfer tube in the body of the absorber having the lowest pressure. There is a problem in that the absorption action is weakened significantly reduced the capacity of the absorption refrigerator. The generation of non-condensable gases is particularly pronounced in hot regenerators.

Therefore, in order to suppress the generation of the non-condensable gas, an inhibitor such as molybdate, chromic acid, or nitric acid is added to the lithium bromide aqueous solution, and the action of the inhibitor stabilizes the metal surface and forms a uniform oxide film. It is configured to suppress the generation of non-condensable gas by the. However, since the inhibitor is gradually consumed to form an oxide film during the operation of the absorption refrigerator and the amount thereof is insufficient, it is necessary to analyze the lithium bromide aqueous solution to confirm the amount of the inhibitor, and to replenish the consumed portion. In addition, during the initial operation, since an oxide film is formed on the inner surface of the absorption refrigerator, a large amount of inhibitor is consumed, and an excess inhibitor is added before the operation starts.

By the way, in the high concentration aqueous lithium bromide solution, the solubility of the inhibitor is much influenced by the concentration of the lithium bromide aqueous solution rather than the temperature and alkalinity, and the higher the concentration of the lithium bromide aqueous solution, the lower the solubility of the inhibitor. In the case of a general absorption chiller, the concentration of the lithium bromide aqueous solution is 56-57 wt% in the thinnest case and 62-63 wt% in the darkest case in the cold water preparation, and the excess inhibitor added has a high concentration of the lithium bromide solution in high concentration. The precipitates are crystallized and precipitated in a high concentration aqueous solution flow path of a low temperature heat exchanger having a slow flow rate. As a result, although the total amount of inhibitor is excessive, the amount circulating with the aqueous solution of lithium bromide decreases, and in particular, the inhibitor does not flow into the hot regenerator which is most needed, so that the effect of the inhibitor can be sufficiently obtained. There is no problem. Moreover, even if it replenishes abundantly, it will become ineffective. In addition, crystallized crystals may precipitate and cause pitching corrosion.

In addition, the added inhibitor suppresses the operation of the heating source of the high temperature regenerator of the dual-effect absorption chiller, or the operation of the heating source of the high temperature regenerator is automatically stopped because the temperature of the produced cold water is lowered to a predetermined temperature or less. After that, when the temperature of the lithium bromide aqueous solution falls, it crystallizes and precipitates in the part with high concentration of the lithium bromide aqueous solution. Therefore, in order to prevent this, normally, after operation | movement of the heating source of a high temperature regenerator is stopped, operation | movement of an aqueous solution pump and a refrigerant circulation pump is continued, and dilution operation is performed, and the density | concentration of the lithium bromide aqueous solution is reduced. In such a dilution operation, the crystals of the inhibitor crystallized and precipitated in the high concentration aqueous solution flow path of the low temperature heat exchanger are also dissolved. However, at the concentration (53 to 55 wt%) during the dilution operation, the crystals cannot be dissolved with excellent efficiency. There is a shortage of inhibitors that dissolve in aqueous lithium bromide solution, so it is necessary to add the inhibitors again, and the work is cumbersome.

In addition, when the above dilution operation is performed, it takes a long time to raise the concentration of the lithium bromide aqueous solution to a predetermined concentration at the time of restarting the operation, and the starting characteristic is lowered. Therefore, in recent years, the dilution operation time before the operation stops tends to be shortened in order to improve the startup characteristics of the absorption chiller, and the stop time at high concentration becomes longer, making it difficult to dissolve the determined inhibitor, and stopping at low ambient temperature. In some cases, a high concentration of aqueous solution is determined and operation is impossible.

It is an object of the present invention to provide a dual utility cold / hot water machine which solves the above problems.

The dual-effect absorption chiller according to the present invention includes a high temperature regenerator, a low temperature regenerator, a condenser, an evaporator, an absorber, a low temperature heat exchanger, and a high temperature heat exchanger, and a double effect absorption chiller using an aqueous solution of an absorber and water as a refrigerant. The refrigerator is provided with the supply path provided so that the liquid refrigerant in an evaporator may be supplied in the flow path of the high concentration absorbent aqueous solution of a low temperature heat exchanger, and the said supply path is provided with the valve | bulb.

In addition, the dual-effect absorption chiller according to the present invention includes a high temperature regenerator, a low temperature regenerator, a condenser, an evaporator, an absorber, a low temperature heat exchanger, and a high temperature heat exchanger, and a double effect using an aqueous solution of an absorber and water as a refrigerant. An absorption chiller, characterized by comprising a supply passage provided to supply a low concentration absorbent aqueous solution in an absorber into a flow path of a high concentration absorbent aqueous solution of a low temperature heat exchanger, wherein the supply passage is provided with a valve.

The concentration of the absorbent in the flow path of the high-density absorbent aqueous solution of the low-temperature heat exchanger in which the supersaturated inhibitor is precipitated gradually dilutes during the dilution operation, but stops at the concentration of about 53 to 55 wt% at the end of the operation.

A supply passage is provided for supplying the liquid refrigerant in the evaporator or the low concentration absorbent aqueous solution in the absorber into the flow path of the high concentration absorbent aqueous solution of the low temperature heat exchanger.If a valve is installed in the supply passage, the valve is opened during the dilution operation or the end of the dilution operation. Through the supply passage, the liquid refrigerant or the low concentration absorbent aqueous solution may be supplied into the flow path of the high concentration absorbent aqueous solution of the low temperature heat exchanger. Therefore, the aqueous solution in the flow path of the high concentration absorbent aqueous solution of the low temperature heat exchanger can be supplied. Therefore, the absorbent concentration of the aqueous solution in the flow path of the high concentration absorbent aqueous solution of the low temperature heat exchanger is lowered, and the crystals of the precipitated inhibitor are dissolved. As a result, the inhibitor can be diffused as a whole when the operation is resumed to effectively suppress the generation of non-condensable gas. In addition, occurrence of pitching corrosion due to precipitated crystals can be prevented. In addition, the number of refills of the inhibitor is reduced, and the maintenance becomes easy. In addition, regardless of the length of the dilution operation time, the crystals of the inhibitor precipitated in the high concentration absorbent aqueous solution flow path of the low temperature heat exchanger can be dissolved, thereby reducing the dilution operation time and diluting the high concentration aqueous solution to reduce the outside temperature. The problem of crystallization of the aqueous solution can be prevented from occurring. Therefore, the starting characteristic at the time of restarting operation can be improved.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In this embodiment, the dual effect absorption chiller is a dual effect absorption chiller. In addition, the same code | symbol is attached | subjected to the same thing and the same part through the conductive surface.

1 is a schematic configuration diagram of a dual-effect absorption cold and hot water heater according to an embodiment of the present invention.

In FIG. 1, the dual-effect absorption cold / hot water machine is a cold / hot water solution using a lithium bromide solution of water as a refrigerant and lithium bromide as an absorbent, and is used to heat a low concentration lithium bromide solution (a low concentration absorbent aqueous solution) by a heating burner (1). A high-temperature regenerator 2, a separator 3 for separating high-temperature medium lithium bromide solution and water vapor (gas-phase refrigerant) transferred from the high-temperature regenerator 2, and a medium lithium bromide solution transferred in the separator 3, The low temperature regenerator (4) and the condenser (5) for cooling and condensing the water vapor passed through the low temperature regenerator (4) to obtain a high concentration lithium bromide solution (high concentration absorbent aqueous solution) by heating with water vapor transferred from the separator (3). 5) Absorption of water (liquid refrigerant) from the evaporator 6, which evaporates the water (liquid refrigerant), and water vapor generated in the evaporator 6 into the concentrated lithium bromide solution transferred from the low temperature regenerator 4. A low concentration lithium bromide solution transferred from the low temperature regenerator 4 to the absorber 7, and a low concentration lithium bromide solution transferred from the absorber 7 to the high temperature regenerator 2 to obtain a low concentration lithium bromide aqueous solution by dilution. A low temperature heat exchanger (8) for exchanging heat, and a low concentration lithium bromide aqueous solution passed through the low temperature heat exchanger (8), and a high temperature heat exchanger for exchanging a medium concentration lithium bromide solution transferred from the separator (3) to the low temperature regenerator (4). (9) is provided.

The low temperature regenerator 4 and the condenser 5 are partitioned in one fuselage and are provided in one place. The low temperature regenerator 4 is provided with the heater 11 in the fuselage, and the steam obtained by the separator 3 is transferred to one end of the heater 11 so that the water vapor passing through the heater 11 is in the condenser 5. Configured to be transported. The condenser 5 includes a coolant flow tube 12 in the body, and cools the water vapor generated in the low temperature regenerator 4 and the water vapor transferred from the heater 11 by the coolant flowing in the coolant flow tube 12. It is configured to liquefy condensation.

The evaporator 6 and the absorber 7 are partitioned in one fuselage and are provided in one place. The evaporator 6 includes a watering device 13 and a water flow pipe 14 (heat transfer pipe) in the body. And the water conveyed from the condenser 5 is sprayed on the water flow pipe 14 by the sprinkler 13. The sprinkled water is configured to take the heat of vaporization from the water flowing in the water flow tube 12 and evaporate to cool the water, thereby producing cold water. The cold water produced is used for cooling. In addition, water remaining in the lower portion flowing downward without evaporating from the evaporator 6 is transferred to the watering device 13 again from the lower end of the evaporator 6 via the water circulation pipe 16 by the water circulation pump 15. It is configured to be sent.

The absorber 7 has a watering device 17 and a cooling water flow pipe 18 in the body. The high concentration lithium bromide solution transferred from the low temperature regenerator 4 is sprayed on the cooling water flow pipe 18 by the sprinkler 17 to form a liquid film on the surface thereof, and the liquid film is cooled water flowing in the flow pipe 18. It is configured to absorb water vapor while cooling with a low concentration aqueous lithium bromide solution. The low concentration lithium bromide solution thus obtained is transferred from the absorber 7 to the high temperature regenerator 2 via the low temperature heat exchanger 8 and the high temperature heat exchanger 9 by the aqueous solution circulation pump 19. Thereafter, it is transferred to the low temperature regenerator 4, concentrated, and then passed through the low temperature heat exchanger 8 to reflux to the absorber 7. The cooling water which has passed through the cooling water flow pipe 18 is moved to the cooling water flow pipe 12 of the condenser 5.

In addition, between the separator 3 and the evaporator 6, a pipe 10 for supplying the lithium bromide aqueous solution in the separator 3 to the evaporator 6 is provided, and the valve 20 is provided in the middle of the pipe 10. It is installed. Then, the valve 20 is opened at the time of producing hot water, and the hot lithium bromide aqueous solution heated by the heating burner 1 in the high temperature regenerator 2 and transferred to the separator 2 is sent to the evaporator 6. The water flowing through the water flow pipe 14 is heated to produce hot water. In the production of hot water, the lithium bromide aqueous solution does not have a concentration step, so that the writing concentration is diluted (51 to 52 wt%) as compared with the production of cold water, and the overall concentration is uniform. Therefore, the excessively added inhibitor crystals generated during cold water dissolution dissolve, so that the amount of inhibitor in the circulating lithium bromide aqueous solution increases, so that replenishment is unnecessary.

Since the structure and operation | movement to the excitation of the dual-effect absorption cold-hot water group to here are known, detailed description is abbreviate | omitted.

The water in the evaporator 6 is supplied to the high concentration lithium bromide aqueous solution flow path of the low temperature heat exchanger 8 between the discharge side part of the water circulation pump 15 in the water circulation pipe 16 and the low temperature heat exchanger 8. A supply passage 21 is provided. The solenoid valve 22 is provided in the middle of the supply path 21.

Here, the heating burner 1 of the high temperature regenerator 2 is stopped when the temperature of the water passing through the water flow pipe 14 at the time of cold water production becomes a predetermined temperature, or when the operation stop switch is operated. . Even after the burner 1 is stopped, the dilution operation is performed, and the water circulation pump 15 and the aqueous solution circulation pump 19 continue to operate to absorb water vapor in the lithium bromide aqueous solution in the absorber 7 so that the aqueous solution concentration gradually decreases. do. Then, after the predetermined set time elapses or when the temperature of the high temperature regenerator 1 drops to the predetermined set temperature, only the aqueous solution circulation pump 19 is stopped. At the same time, the solenoid valve 22 is opened. As a result, water is transferred to the high concentration aqueous solution flow path of the low temperature heat exchanger 8 by the water circulation pump 15, and the concentration of the aqueous solution in the flow path is reduced to about 20 to 30 wt%. As a result, the concentration of the aqueous solution in the high concentration aqueous solution flow path of the low temperature heat exchanger 8 decreases, and the excess inhibitor determined in this flow path is dissolved in a short time. Thereafter, the water circulation pump 15 is stopped and the solenoid valve 22 is closed. The operation of the water circulation pump 15 and the transition from the open state of the solenoid valve 22 to the closed state are made in accordance with the time set by the timer.

When the operation signal is applied again, the low concentration aqueous solution in the regenerator 2 is heated by the burner 1, and the aqueous solution circulation pump 19 and the water circulation pump 15 operate to flow out the lithium bromide aqueous solution. 8) Since the inhibitor started to dissolve in the absorber (7) is passed through the low temperature heat exchanger (8) and the high temperature heat exchanger (9) and sent to the high temperature regenerator (1), the excessively injected inhibitor is effectively used as a whole. Thus, generation of non-condensable gas is effectively suppressed. Therefore, the number of inhibitor supplements can be reduced by the addition of excess inhibitor, and the number of repair and maintenance is also reduced.

2 to 4 show a second embodiment of the present invention.

In FIGS. 2-4, the part of the discharge side of the aqueous solution circulation pump 19 in the piping 23 which communicates the absorber 7 and the low temperature heat exchanger 8 in the middle of the supply path 21 is shown. A pilot type on / off valve 24 is provided to open and close the pressure as a pilot pressure. The supply passage 21 is a first conduit 21a connecting the water circulation pipe 16 and the valve box 25 of the on-off valve 24 and the high concentration of the valve box 25 and the low temperature heat exchanger 8. The 2nd conduit 21b which connects an aqueous solution flow path is provided. Moreover, the branch pipe 23a branched from the said piping 23 is connected to the valve box 25 of the opening / closing valve 24. As shown in FIG. The valve seat 26 is provided in the connection end part of the 2nd conduit 21b to the valve box 25. As shown in FIG. The bellows 27 which normally contracts is attached to the connection end part of the branch pipe 23a to the valve box 25, and the valve body 28 which press-contacts the valve seat 26 at the front-end | tip of the bellows 27 is attached. ) Is attached.

The pump head difference between the refrigerant circulation pump 15 and the aqueous solution circulation pump 19 is about 1.0 kg / m 2 G. When both pumps 15 and 19 are in operation, the absorber 7 and the low temperature as shown in FIG. The bellows 27 expands by making the pressure of the part of the discharge side of the aqueous solution circulation pump 19 in the piping 23 which communicates the heat exchanger 8 into a pilot pressure, and the valve body 28 is a valve seat 26. ), The on-off valve 24 is closed, and the inflow of water into the second conduit 21b is prevented.

After completion of the dilution operation, when only the aqueous solution circulation pump 19 stops, as shown in FIG. 4, the bellows 27 contracts, and the valve body 28 is separated from the valve seat 26 to open and close the valve 24. . As a result, water flows into the low temperature heat exchanger 8 through the second conduit 21b, and the excess inhibitor determined in the high concentration aqueous solution flow path of the low temperature heat exchanger 8 as in the case of the embodiment of FIG. Dissolves.

5 and 6 are pilot types for opening and closing the pressure of a portion on the discharge side of the aqueous solution circulation pump 19 in the pipe 23 for communicating the absorber 7 and the low temperature heat exchanger 8 as pilot pressures. The opening and closing modification is shown.

5 and 6, the valve seat 32 is provided at the connecting end of the second conduit 21b of the on-off valve 30 to the valve box 31, and in the valve box 31, the valve seat 32 is provided. The 1st valve body 33 which press-contacts the valve seat 32 is provided. Moreover, the valve seat 34 is provided in the connection end part of the 1st conduit 21a to the valve box 31, and the 2nd valve body which press-contacts this valve seat 34 in the valve box 31 ( 35) is installed. The guide rods 38 and 39 provided in the first valve body 33 are configured to move by being guided. Moreover, the 1st valve body 33 is urged toward the branch pipe 23a side by the tension coil spring 41. As shown in FIG. The 2nd valve body 35 is urged by the tension coil spring 42 to the 1st conduit 21a side.

In such a configuration, when both pumps 15 and 19 are operating, the aqueous solution circulation pump in the piping 23 which communicates the absorber 7 and the low temperature heat exchanger 8 as shown in FIG. The first valve body 33 is press-contacted to the valve seat 32 using the pressure of the portion on the discharge side of 19 as the pilot pressure, and the second valve body 35 is the valve seat 34 by the pressure. The on-off valve 30 is closed by contact with the valve, and the inflow of water into the second conduit 21b is prevented.

After completion of the dilution operation, when only the aqueous solution circulation pump 19 stops, the first valve body 33 falls from the valve seat 32 by the tension coil spring 41 as shown in FIG. As a result, the second valve body 35 is separated from the valve seat 34 to open and close the valve 30. As a result, water flows into the low temperature heat exchanger 8 through the second conduit 21b, and is determined in the high concentration aqueous solution flow path of the low temperature heat exchanger 8 in the same manner as in the embodiment shown in FIG. Excess inhibitor dissolves.

7 shows another embodiment of the present invention.

In FIG. 7, the part of the discharge side of the aqueous solution circulation pump 19 in the piping 23 which connects the absorber 7 and the low concentration aqueous solution flow path of the low temperature heat exchanger 8, and the high concentration of the low temperature heat exchanger 8 is shown. A supply passage 45 for supplying the low concentration aqueous solution obtained from the absorber 7 to the high concentration aqueous solution passage of the low temperature heat exchanger 8 is provided between the aqueous solution passages. The solenoid valve 46 is provided in the middle of the supply path 45.

When the solenoid valve 46 is opened during the dilution operation, the low concentration lithium bromide aqueous solution in the absorber 7 is transferred into the high concentration aqueous solution flow path of the low temperature heat exchanger 8 by the aqueous solution circulation pump 19, and the concentration of the aqueous solution in this flow path. Is lowered. As a result, the concentration of the aqueous solution in the high concentration aqueous solution flow path of the low temperature heat exchanger 8 is decreased, so that the excess inhibitor determined in this flow path is dissolved.

In all the embodiments described above, the present invention has been described in the case where the present invention is applied to an absorption cold / hot water machine, but is not limited thereto.

Claims (7)

In the dual-effect absorption chiller having a high temperature regenerator, a low temperature regenerator, a condenser, an evaporator, an absorber, a low temperature heat exchanger, and a high temperature heat exchanger, and using an aqueous solution of an absorbent and water as a refrigerant, And a supply passage provided to supply the liquid refrigerant in the evaporator to the flow path of the high concentration absorbent aqueous solution of the low temperature heat exchanger, wherein the supply passage is provided with a valve. The water supply system according to claim 1, wherein water remaining in the lower portion flowing down without evaporating in the evaporator is returned by the circulation pump to return to the upper portion of the evaporator through the circulation pipe, wherein the supply passage is a water circulation in the water circulation pipe. A valve is installed in the supply passage while being provided between the discharge side of the pump and the low temperature heat exchanger, and water remaining in the lower part of the evaporator at the time of opening the valve is used for the high concentration absorbent aqueous solution of the low temperature heat exchanger. Double effect absorption chiller, characterized in that configured to be transported in the flow path. The low concentration absorbent aqueous solution obtained in the absorber is configured to be sent to the low temperature heat exchanger through a pipe by an aqueous solution circulation pump, and the valve is an electromagnetic valve which is opened when the aqueous solution circulation pump is stopped. Heavy-duty absorption chiller. The low concentration absorbent aqueous solution obtained in the absorber is configured to be sent to the low temperature heat exchanger through a pipe by an aqueous solution circulation pump, and the valve is opened and closed by using the pressure at the discharge side of the aqueous solution circulation pump in the piping as the pilot pressure. A dual effect absorption chiller, characterized in that the pilot on-off valve. In the dual-effect absorption chiller comprising a high temperature regenerator, a low temperature regenerator, a condenser, an evaporator, an absorber, a low temperature heat exchanger, and a high temperature heat exchanger, and using an aqueous solution of an absorber and water as a refrigerant, And a supply passage provided to supply the low concentration absorbent aqueous solution in the absorber into the flow path of the high concentration absorbent aqueous solution of the low temperature heat exchanger, wherein the supply passage is provided with a valve. The low concentration absorbent aqueous solution obtained in the absorber is configured to be transferred to a low temperature heat exchanger through a pipe by an aqueous solution circulation pump, and the supply passage is installed between the low temperature heat exchanger and the portion of the discharge side of the aqueous solution circulation pump in the pipe. And at the same time, the supply passage is provided with a valve, and the low concentration absorbent aqueous solution obtained from the absorber at the time of opening the valve is configured to be transferred into the flow path of the high concentration absorbent aqueous solution of the low temperature heat exchanger by an aqueous solution circulation pump. Heavy-duty absorption chiller. 7. The dual effect absorption chiller of claim 6, wherein the valve is a solenoid valve.