JP2008116173A - Absorption type refrigerating machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To surely prevent freezing of cold water in an evaporator when a cooling water pump is singly started when an operation is stopped, particularly, in a double-effect absorption-type refrigerating machine. <P>SOLUTION: In this absorption type refrigerating machine wherein a high-temperature regenerator 1, a low-temperature regenerator 2, a condenser 3, an evaporator 4, an absorber 5, a high-temperature heat exchanger 6 and a low-temperature heat exchanger 7 are connected by pipe conduits, a cooling water pipe conduit 11 is formed to pass through the inside of the condenser 3 after passing through the inside of the absorber 5, a cold water pipe conduit 14 at a load side is formed in a state of passing through the inside of the evaporator 4, and further a thick absorbing liquid pump 10 for supplying the thick absorbing liquid from the low-temperature regenerator 2 to the absorber 5, a dilute absorbing liquid pump 8 for supplying a dilute absorbing liquid from the absorber 5 to the high-temperature regenerator 1, a refrigerant liquid pump 1 for supplying refrigerant liquid stored at a bottom portion of the evaporator 4 to a refrigerant liquid spraying pipe 4a of the evaporator 4, and the cooling water pump 12 for supplying the cooling water to the cooling water pipe conduit 11 are disposed, a cold/hot water pump 15 disposed in a cold/hot water pipe conduit 14 at a load side is interlockingly operated when the cooling water pump 12 is singly started when the operation is stopped. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an absorption refrigerator, and more particularly to an absorption refrigerator in a double-effect absorption refrigerator that prevents cold water on the load side from freezing inside an evaporator during operation stoppage.

  In general, double-effect absorption refrigerators are connected to high-temperature regenerators, low-temperature regenerators, condensers, evaporators, absorbers and high-temperature heat exchangers, and low-temperature heat exchangers through pipe lines. In addition, a concentrated absorption liquid pump, a rare absorption liquid pump, a refrigerant liquid pump, an on-off valve, and the like are provided to constitute an absorption liquid circulation line and a refrigerant circulation line. Then, the cool / warm water returned from the load side by the heat of evaporation of the refrigerant liquid in the evaporator is cooled and supplied to the load side to obtain a cooling or freezing action. Moreover, not only cooling but also heating can be performed by switching the pipeline. As the absorbing liquid, an aqueous lithium bromide solution is usually used, and water is used as the refrigerant.

  In the double-effect absorption refrigerator, a cooling water pipe that passes through the inside of the condenser after passing through the inside of the absorber is provided, and the cooling water is circulated through the cooling water pipe so that the concentration inside the absorber is high. Cooling the concentrated absorption liquid sprayed from the absorption liquid spraying tube to enhance the absorption function of absorbing the refrigerant vapor flowing from the evaporator into the absorber, and the refrigerant vapor flowing from the low temperature regenerator into the condenser inside the condenser The cooling function is performed to condense into a refrigerant liquid.

  Double-effect absorption refrigerators are used, for example, in office building air conditioners and commercial refrigerators. However, because cooling towers are installed outdoors, they are cooled by a drop in temperature during shutdown. Cooling water may freeze in the water pipe. If the cooling water freezes, the circulation of the cooling water will deteriorate when the operation is resumed thereafter, or the circulation of the cooling water will not be caused and the performance will be deteriorated, and the cooling water pipe may be cracked or ruptured. There is.

In order to prevent such a situation, in an air conditioner configured to be capable of cooling operation using an absorption chiller, the cooling water does not freeze in the cooling water pipe even if the temperature drops while the air conditioner is stopped. A technique for doing so is disclosed in, for example, Patent Document 1. In this case, when the cooling water temperature in the cooling water pipe is likely to be affected by the outside air and the temperature is likely to drop as the temperature drops and there is a risk of freezing, the cooling water pump is activated and the outside air has a relatively large heat capacity. By supplying the cooling water in the cooling tower storage part which is not easily influenced by the cooling water pipe to the cooling water pipe, the cooling water is prevented from freezing in the cooling water pipe.
JP 2001-99474 A

  However, according to the above prior art, it relates to the prevention of freezing of the cooling water for cooling the absorber and the condenser in the absorption refrigerator, and the freezing prevention of the cold / warm water circulating between the load side and the evaporator. It is not about. No measures have been taken in the past with respect to the prevention of freezing of the cold / hot water, and only a warning is given to the user. It is difficult to prevent cold / hot water from freezing by simply calling attention.

  An object of the present invention is to make it possible to reliably prevent freezing of cold / warm water when a cooling water pump is independently activated when the operation is stopped, particularly in a double-effect absorption refrigerator.

  As means for achieving the above object, the invention of claim 1 is characterized in that a high temperature regenerator, a low temperature regenerator, a condenser, an evaporator, an absorber, a high temperature heat exchanger, and a low temperature heat exchanger are connected by a pipe. In addition, a cooling water pipe that passes through the inside of the condenser after passing through the inside of the absorber is provided, and a cold / hot water pipe on the load side that passes through the inside of the evaporator is provided. A concentrated absorbent pump for supplying the absorbent, a rare absorbent pump for supplying the rare absorbent from the absorber to the high-temperature regenerator, and a refrigerant provided at the top of the evaporator with the refrigerant liquid stored at the bottom of the evaporator In an absorption refrigeration machine provided with a refrigerant liquid pump that supplies liquid spray pipes and a cooling water pump that supplies cooling water to the cooling water pipes, when the cooling water pump is started alone when operation is stopped, Cold / hot water pump provided in the cold / hot water pipe on the side Wherein the interlocking driving.

  The invention of claim 2 is that the high-temperature regenerator, the low-temperature regenerator, the condenser, the evaporator, the absorber, the high-temperature heat exchanger, and the low-temperature heat exchanger are connected by a pipe line and after passing through the inside of the absorber. A cooling water pipe that passes through the inside of the condenser, a cold-hot water pipe on the load side that passes through the inside of the evaporator, and a concentrated absorbing liquid pump that supplies concentrated absorbing liquid from the low-temperature regenerator to the absorber; A rare absorption liquid pump for supplying a rare absorption liquid from the absorber to the high temperature regenerator, a refrigerant liquid pump for supplying the refrigerant liquid stored at the bottom of the evaporator to a refrigerant liquid spraying pipe provided at the top of the evaporator, In an absorption refrigeration machine provided with a cooling water pump for supplying cooling water to the cooling water pipe, the refrigerant liquid stored at the bottom of the evaporator by the refrigerant liquid pump is dispersed in the refrigerant liquid provided at the top of the evaporator Downstream of the refrigerant liquid pump in the pipeline that supplies the pipe And a refrigerant liquid bypass line connecting the absorber and the bottom of the absorber, and an opening / closing valve is provided in the refrigerant liquid bypass line, and when the cooling water pump is activated alone when the operation is stopped, the opening / closing valve is opened. A part of the refrigerant liquid in the evaporator is supplied to the absorber via a refrigerant liquid bypass line by a refrigerant liquid pump.

  In the invention of claim 3, the high-temperature regenerator, the low-temperature regenerator, the condenser, the evaporator, the absorber, the high-temperature heat exchanger, and the low-temperature heat exchanger are connected by a pipe line and after passing through the inside of the absorber. A cooling water pipe that passes through the inside of the condenser, a cold-hot water pipe on the load side that passes through the inside of the evaporator, and a concentrated absorbing liquid pump that supplies concentrated absorbing liquid from the low-temperature regenerator to the absorber; A rare absorption liquid pump for supplying a rare absorption liquid from the absorber to the high temperature regenerator, a refrigerant liquid pump for supplying the refrigerant liquid stored at the bottom of the evaporator to a refrigerant liquid spraying pipe provided at the top of the evaporator, In an absorption refrigeration machine provided with a cooling water pump for supplying cooling water to the cooling water pipe, a cooling water bypass pipe that connects the upstream side of the cooling water pipe with respect to the absorber and the downstream side of the absorber is provided. In addition, an opening / closing valve is provided in the cooling water bypass pipeline. During shutdown, when the cooling water pump is alone activated, characterized by a portion of the cooling water by opening the on-off valve be distributed to the coolant bypass line.

  According to the first aspect of the present invention, in the dual effect absorption chiller, when the cooling water pump is activated independently when the operation is stopped, the cold / hot water pump provided in the cold / hot water pipe on the load side is operated in conjunction. As a result, the hot and cold water is prevented from stagnation in the evaporator. Thereby, it can avoid that cold / warm water is cooled too much inside an evaporator by the influence of cooling water. As a result, freezing of cold / hot water can be prevented.

  According to the invention of claim 2, in the double-effect absorption chiller, when the cooling water pump is independently activated when the operation is stopped, the on-off valve is opened and a part of the refrigerant liquid is bypassed by the refrigerant liquid pump. By supplying to an absorber via a pipe line, the density | concentration of the rare absorption liquid in an absorber can be reduced. As a result, the ability to absorb the refrigerant vapor is reduced by diluting the rare absorption liquid, so that the self-evaporation amount of the refrigerant liquid from the evaporator side can be reduced. As a result, it is possible to prevent freezing by keeping the cooling of cold / hot water by heat of evaporation low.

  According to the invention of claim 3, in the double-effect absorption chiller, when the cooling water pump is independently activated at the time of operation stop, the on-off valve is opened and a part or all of the cooling water is supplied to the cooling water bypass conduit. It is possible to reduce the flow rate of the cooling water passing through the inside of the absorber. Thereby, it can suppress that cold / warm water is cooled too much inside an evaporator by the influence of the cooling water which passes the inside of an absorber. As a result, freezing of cold / hot water can be prevented.

  Next, an absorption refrigerator according to an embodiment of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a configuration diagram showing a first embodiment of an absorption refrigerator according to the present invention, and a high temperature regenerator 1, a low temperature regenerator 2, a condenser 3, an evaporator 4, an absorber 5, and a high temperature heat exchanger. 6, the low-temperature heat exchanger 7 and the like are connected by a pipe, and an absorption liquid circulation path and a refrigerant circulation path are configured.

  In the high-temperature regenerator 1, the rare absorbent returned from the absorber 5 by the rare absorbent pump 8 through the pipe line R1 is accommodated, and this rare absorbent is heated by the burner 9 to be contained in the rare absorbent. The refrigerant liquid is vaporized and separated. As a result, the rare absorption liquid becomes a medium concentration absorption liquid and is supplied to the low temperature regenerator 2 via the pipe line R2, but the rare absorption liquid flowing through the pipe line R1 when passing through the high temperature heat exchanger 6 on the way. The heat is dissipated by exchanging heat with the low-temperature regenerator 2 to be dissipated. On the other hand, the evaporated refrigerant vapor is supplied to the condenser 3 via the pipe line R3, but when passing through the low-temperature regenerator 2, the refrigerant vapor is exchanged with the medium-concentrated absorbent contained in the low-temperature regenerator 2. By exchanging heat, the heat is dissipated to become a gas-liquid mixed liquid, and further condensed to become a refrigerant liquid, which is stored at the bottom of the condenser 3.

  In the low temperature regenerator 2, the medium concentrated absorbent supplied from the high temperature regenerator 1 is heated by the refrigerant vapor passing through the low temperature regenerator 2, and the refrigerant liquid in the medium concentrated absorbent is vaporized and evaporated. Separated. As a result, the medium concentrated absorbent becomes a concentrated absorbent and is supplied to the absorber 5 via the conduit R4 by the concentrated absorbent pump 10, but when passing through the low temperature heat exchanger 7 on the way, the high temperature regenerator The heat is exchanged with the rare absorbent flowing through the pipe R <b> 1 toward the heat radiation 1, and the heat is dissipated to be supplied to the absorbent dispersion pipe 5 a of the absorber 5. On the other hand, the refrigerant vapor evaporated in the low temperature regenerator 2 passes over the upper part of the partition wall and flows into the condenser 3 side.

  In the condenser 3, the refrigerant vapor flowing from the low temperature regenerator 2 is cooled and condensed by the cooling water passing through the condenser 3, and becomes a refrigerant liquid and accumulates at the bottom of the condenser 3. The cooling water passes through the condenser 3 after passing through the absorber 5 through the cooling water pipe 11 by the cooling water pump 12.

  In the evaporator 4, the refrigerant liquid accumulated at the bottom of the condenser 3 is supplied via the pipe line R 5, and is supplied by the refrigerant liquid pump 13 to the refrigerant liquid spray pipe 4 a via the pipe line R 6. The refrigerant liquid sprayed from the refrigerant liquid spray pipe 4a absorbs heat and evaporates by exchanging heat with the cold / hot water flowing through the evaporator 4 via the cold / hot water pipe 14 by the cold / hot water pump 15. To do. The cold / hot water flowing through the cold / hot water pipe 14 is cooled by this evaporation heat, and supplied from the evaporator 4 to a load (not shown) such as a refrigerator. From the load side, cold / hot water whose temperature has risen is returned to the evaporator 4 and circulated. On the other hand, the refrigerant vapor evaporated in the evaporator 4 flows into the absorber 5 through the partition slit portion.

  In the absorber 5, the concentrated absorbent sprayed from the absorbent spray pipe 5a is cooled by the cooling water flowing through the cooling water pipe 11, and the refrigerant vapor is absorbed by the cooled concentrated absorbent. . When the concentration of the concentrated absorbent is high and the liquid temperature is low, the ability to absorb the refrigerant vapor is improved. The concentrated absorbent that has absorbed the refrigerant vapor becomes a rare absorbent and accumulates at the bottom of the absorber 5. The rare absorbent stored at the bottom of the absorber 5 is returned to the high temperature regenerator 1 via the pipe R1 by the rare absorbent pump 8, but when passing through the low temperature heat exchanger 7 on the way, Heat is exchanged with the medium temperature concentrated absorbent flowing from the regenerator 2 toward the absorber 5 and then heated, and then passes through the high temperature heat exchanger 6 from the high temperature regenerator 1 to the low temperature regenerator 2. Then, it is reheated by exchanging heat with the flowing hot high-concentration absorbent, and then returned to the high temperature regenerator 1.

  As a result, the high temperature regenerator 1 → (pipe R2) → low temperature regenerator 2 → (pipe R4) → absorber 5 → (pipe R1) → the circulation path of the absorbing liquid system circulating to the high temperature regenerator 1 , High temperature regenerator 1 → (line R3) → condenser 3 → (line R5) → evaporator 4 → (line R6) → evaporator 4 → absorber 5 → (line R1) → high temperature regenerator 1 And a refrigerant system circulation path that circulates to the outside.

  Also, an on-off valve 16 provided in a pipe R7 branched from the pipe R3 and connected to the absorber 5, and an open / close valve provided in a pipe R8 branched from the pipe R2 and connected to the absorber 5. Both the valve 17 and the open / close valve 18 provided in the pipe R9 branched from the pipe R6 and connected to the bottom of the absorber 5 are opened, and the absorber 5 and the condenser are not activated without starting the cooling water pump 12. 3, the refrigerant vapor generated in the high-temperature regenerator 1 has a flow resistance from the middle of the pipe R3 when the burner 9 is ignited and the rare absorbent is heated by the high-temperature regenerator 1 without supplying cooling water. It is supplied to the absorber 5 via a small line R7. And the refrigerant | coolant vapor | steam supplied to the absorber 5 flows into the evaporator 4 side, heat-condenses with the cold / hot water which passes the inside of the evaporator 4 through the cold / hot water pipe line 14, and is condensed, The condensation heat at this time Heat the cold / hot water with. By supplying this heated cold / warm water to the load side, it is possible to operate in the heating mode. In the cooling or freezing mode operation, the on-off valves 16, 17, and 18 are all closed. Moreover, it is preferable that all of the on-off valves 16, 17, 18 are electromagnetic valves so that they can be controlled by a control device (not shown).

  In the heating mode operation, the refrigerant liquid condensed in the evaporator 4 accumulates at the bottom of the evaporator 4 and is absorbed by the refrigerant liquid pump 13 through the pipe R9 having a small channel resistance while flowing through the pipe R6. 5 is supplied. Then, the medium-concentrated absorption liquid generated in the high-temperature regenerator 1 is supplied to the absorber 5 from the middle of the pipe R2 through the pipe R8 having a small flow resistance, and the pipe R9 in the absorber 5 Is mixed with the refrigerant liquid supplied via the refrigerant, and becomes a rare absorbent, which is returned to the high temperature regenerator 1 via the pipe R1 by the rare absorbent pump 8.

  In the present embodiment, cooling or refrigeration mode operation is performed, and cold / hot water is prevented from freezing inside the evaporator 4 during operation stop due to a decrease in outside air temperature in winter. Even if the operation of the absorption chiller is stopped, it is preferable that the cooling water pump 12 continues to operate to circulate the cooling water to a cooling tower (not shown). The cooling tower is usually installed outdoors, and in particular in the case of office buildings, it is often installed on the rooftop. For this reason, it is easy to be influenced by the outside air temperature, and when the circulation of the cooling water is stopped with the operation stop of the absorption chiller, the cooling water is easily frozen in the cooling water pipe. In order to avoid this, it is preferable to circulate the cooling water by operating the cooling water pump 12 even when the operation of the absorption refrigerator is stopped.

  In the present embodiment, when the cooling water pump 12 is activated independently when the operation of the absorption refrigerator is stopped, the cold / hot water pump 15 provided in the cold / hot water pipe 14 on the load side is operated in conjunction. To do. When the cooling water pump 12 is operated and the cooling water is circulated to the cooling tower after the absorption refrigerator is stopped, the cooling water is absorbed when passing through the inside of the absorber 5 through the cooling water pipe 11. Cool the vessel 5.

  When the inside of the absorber 5 is cooled by the cooling water, the inside of the evaporator 4 integrated with the absorber 5 is cooled, and the cold / hot water stays in the evaporator 4 through the cold / hot water pipe 14. If it is, it will be overcooled and will cause the cooling water to freeze. The freezing of the cold / hot water does not stop at the region in the evaporator 4 and may extend over a wide area of the cold / hot water pipe 14. Will be reduced. In this embodiment, such a situation is avoided.

  FIG. 2 shows a flowchart in the present embodiment. When the operation signal is turned OFF in step S1, the operation of the absorption refrigerator is stopped. When the operation signal is ON, the operation of the absorption refrigerator is continued.

  When the operation signal of the absorption chiller is turned off, a cooling water pump interlock signal is issued in step S2, and when the signal is on, the cooling water pump 12 is activated alone and the load-side cold / hot water pump 15 is turned on. The start signal is turned ON to start linked operation. And while the cooling water pump interlock signal is ON, the cold / hot water pump 15 continues the linked operation. When the coolant pump interlock signal is turned OFF, the coolant pump 12 is started and stopped, and the start signal of the cold / hot water pump 15 is also turned OFF and stopped.

  In the present embodiment, the cold / hot water pump 15 is operated in conjunction with the cooling water pump 12 when the cooling water pump 12 is activated independently when the absorption chiller is stopped. Can be circulated. For this reason, cold / warm water does not stay in the evaporator 4 via the cold / hot water pipe 14, and excessive cooling of the cold / hot water due to the influence of the cooling water can be avoided. Thereby, freezing of cold / warm water during operation stop can be prevented.

  FIG. 3 is a block diagram showing a second embodiment according to the present invention. In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals as those described above, and detailed description thereof is omitted. In the present embodiment, the refrigerant liquid pump 13 in the pipeline R6 that supplies the refrigerant liquid stored at the bottom of the evaporator 4 by the refrigerant liquid pump 13 to the refrigerant liquid spray pipe 4a provided at the top of the evaporator 4. A refrigerant liquid bypass line 19 that connects the downstream side to the bottom of the absorber 5 is provided, and an on-off valve 20 is provided in the refrigerant liquid bypass line 19. In the illustrated example, the refrigerant liquid bypass line 19 is formed as a bypass line that connects the upstream side and the downstream side of the on-off valve 18 in the line R9 using the line R9. Further, as the on-off valve 20, it is preferable to use an electromagnetic valve or an automatic flow valve.

  In the present embodiment, when the cooling water pump 12 is activated alone when the absorption chiller is stopped, the on-off valve 20 is opened to allow a part of the refrigerant liquid in the evaporator 4 to be discharged by the refrigerant liquid pump 13. The refrigerant is supplied to the absorber 5 through the refrigerant liquid bypass line 19. At this time, the on-off valve 18 of the pipe line R9 is closed.

  The refrigerant liquid stays at the bottom of the evaporator 4 and after the operation is stopped, self-evaporation occurs from the refrigerant liquid in the evaporator 4 which is almost vacuum. The self-evaporated refrigerant vapor flows into the absorber 5 and is absorbed by the rare absorbing liquid staying at the bottom of the absorber 5, but evaporates through the cold / hot water pipe 14 by the heat of evaporation at the time of self-evaporation. The cold / hot water staying in the vessel 4 is cooled. If the cold / hot water is cooled excessively, it will freeze inside the evaporator 4. In this embodiment, such a situation is avoided.

  FIG. 4 shows a flowchart in the present embodiment. When the operation signal is turned OFF in step S1, the operation of the absorption refrigerator is stopped. When the operation signal is ON, the operation of the absorption refrigerator is continued.

  When the operation signal of the absorption chiller is turned off, a coolant pump interlock signal is issued in step S2, and when the signal is turned on, the coolant pump 12 is activated alone and the refrigerant liquid pump 13 is activated. The on-off valve 20 opens for 5 minutes. Immediately thereafter, the on-off valve 20 is closed and the refrigerant liquid pump 13 is stopped. As a result, while the on-off valve 20 is open for a certain time (for example, 5 minutes), a part of the refrigerant liquid accumulated at the bottom of the evaporator 4 by the refrigerant liquid pump 13 is reduced by the pipe line R6. It is fed into the bottom of the absorber 5 through a small refrigerant liquid bypass line 19. On the other hand, when the coolant pump interlock signal is turned off, the coolant pump 12 is stopped and the activation signal of the cold / hot water pump 15 is also turned off and stopped.

  In this embodiment, when the cooling water pump 12 is activated alone when the absorption chiller is stopped, the on-off valve 20 is opened and a part of the refrigerant liquid in the evaporator 4 is supplied to the refrigerant liquid pump 13 by the refrigerant liquid pump 13. Since a predetermined amount is supplied to the absorber 5 through the bypass line 19, the concentration of the rare absorbent in the absorber 5 is lowered. For this reason, since the absorption capability with respect to the refrigerant | coolant vapor | steam self-evaporating in the evaporator 4 falls and the pressure fall in the absorber 5 is suppressed, the self-evaporation amount of a refrigerant | coolant liquid can be restrained small. If the amount of the refrigerant vapor that self-evaporates decreases, excessive cooling of the cold / hot water in the evaporator 4 can be suppressed. Thereby, freezing of cold / warm water during operation stop can be prevented.

  FIG. 5 is a block diagram showing a third embodiment according to the present invention. In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals as those described above, and detailed description thereof is omitted. In the present embodiment, a cooling water bypass pipe 21 connecting the upstream side of the cooling water pipe 11 with respect to the absorber 5 and a downstream side of the absorber 5 is provided, and an opening / closing valve 22 is provided in the cooling water bypass pipe 21. The provided structure is characterized.

  In the present embodiment, when the cooling water pump 12 is activated independently when the absorption chiller is stopped, a part of the cooling water is opened by the cooling water pump 12 and the flow resistance is small. It is circulated through the cooling water bypass pipe 21. For this reason, the flow volume of the cooling water which passes the inside of the absorber 5 through the cooling water pipe line 11 can be decreased. Thereby, it can suppress that cold / hot water is cooled too much inside the evaporator 4, and can prevent freezing of cold / hot water. Note that the on-off valve 22 is closed during normal operation of the absorption refrigerator.

  The present invention is particularly applicable to a double-effect absorption chiller, and prevents the cold-side water on the load side from freezing inside the evaporator when the cooling water pump is started alone when the operation is stopped. Can do.

It is a lineblock diagram showing a 1st embodiment of an absorption refrigerating machine concerning the present invention. It is a flowchart in 1st Embodiment of the absorption refrigerator which concerns on this invention. It is a block diagram which shows 2nd Embodiment of the absorption refrigerator which concerns on this invention. It is a flowchart in 2nd Embodiment of the absorption refrigerator which concerns on this invention. It is a block diagram which shows 3rd Embodiment of the absorption refrigerator which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 High temperature regenerator 2 Low temperature regenerator 3 Condenser 4 Evaporator 5 Absorber 6 High temperature heat exchanger 7 Low temperature heat exchanger 8 Rare absorption liquid pump 9 Burner 10 Concentrated absorption liquid pump 11 Cooling water line 12 Cooling water pump 13 Refrigerant liquid Pump 14 Chilled / hot water pipe 15 Chilled / hot water pump 16, 17, 18 On-off valve 19 Refrigerant liquid bypass line 20 On-off valve 21 Cooling water bypass line 22 On-off valve

Claims (3)

  A high temperature regenerator, a low temperature regenerator, a condenser, an evaporator, an absorber, a high temperature heat exchanger, and a low temperature heat exchanger are connected by a pipe line and pass through the inside of the condenser after passing through the inside of the absorber. A cooling water pipe is provided, a load-side cold / hot water pipe that passes through the inside of the evaporator is provided, a concentrated absorbent pump that supplies concentrated absorbent from the low-temperature regenerator to the absorber, and an absorber to the high-temperature regenerator A rare absorbent pump for supplying the rare absorbent, a refrigerant liquid pump for supplying the refrigerant liquid stored at the bottom of the evaporator to a refrigerant liquid spray pipe provided at the top of the evaporator, and cooling water for the cooling water pipe In an absorption refrigeration machine provided with a cooling water pump to be supplied to the chilled water pump, when the cooling water pump is started alone when the operation is stopped, the chilled water pump provided in the chilled water pipe on the load side is operated in conjunction. Absorption type refrigerator that features.   A high temperature regenerator, a low temperature regenerator, a condenser, an evaporator, an absorber, a high temperature heat exchanger, and a low temperature heat exchanger are connected by a pipe line and pass through the inside of the condenser after passing through the inside of the absorber. A cooling water pipe is provided, a load-side cold / hot water pipe that passes through the inside of the evaporator is provided, a concentrated absorbent pump that supplies concentrated absorbent from the low-temperature regenerator to the absorber, and an absorber to the high-temperature regenerator A rare absorbent pump for supplying the rare absorbent, a refrigerant liquid pump for supplying the refrigerant liquid stored at the bottom of the evaporator to a refrigerant liquid spray pipe provided at the top of the evaporator, and cooling water for the cooling water pipe In the absorption refrigeration machine provided with a cooling water pump for supplying to the refrigerant, a refrigerant liquid stored at the bottom of the evaporator by the refrigerant liquid pump is supplied to a refrigerant liquid spraying pipe provided at the top of the evaporator. , Downstream from the refrigerant liquid pump and the bottom of the absorber In addition, a refrigerant liquid bypass pipe is provided to connect the refrigerant liquid bypass pipe, and an opening / closing valve is provided in the refrigerant liquid bypass pipe. An absorption refrigerating machine in which a part is supplied to an absorber via a refrigerant liquid bypass line by a refrigerant liquid pump.   A high temperature regenerator, a low temperature regenerator, a condenser, an evaporator, an absorber, a high temperature heat exchanger, and a low temperature heat exchanger are connected by a pipe line and pass through the inside of the condenser after passing through the inside of the absorber. A cooling water pipe is provided, a load-side cold / hot water pipe that passes through the inside of the evaporator is provided, a concentrated absorbent pump that supplies concentrated absorbent from the low-temperature regenerator to the absorber, and an absorber to the high-temperature regenerator A rare absorbent pump for supplying the rare absorbent, a refrigerant liquid pump for supplying the refrigerant liquid stored at the bottom of the evaporator to a refrigerant liquid spray pipe provided at the top of the evaporator, and cooling water for the cooling water pipe In the absorption refrigeration machine provided with a cooling water pump for supplying to the cooling water, a cooling water bypass pipe connecting the upstream side of the cooling water pipe with respect to the absorber and the downstream side of the absorber is provided, and the cooling water bypass pipe An open / close valve is provided on the road so that When the cooling water pump is alone activated absorption chiller, wherein a part or all of the cooling water by opening the on-off valve be distributed to the coolant bypass line.

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