JP4952599B2 - Turbo refrigerator - Google Patents

Description

  The present invention relates to a turbo refrigerator equipped with a turbo compressor.

  Conventionally, a turbo turbo refrigerator used for air conditioning of a general building or a factory is known (for example, refer to Patent Document 1). This turbo refrigerator includes, for example, a turbo compressor having a two-stage impeller, an evaporator, a condenser, and an intercooler (economizer).

  The turbo compressor includes a refrigerant suction capacity control unit provided upstream of the impeller, a bearing that supports the impeller that rotates at a high speed, an oil tank that stores lubricating oil supplied to the bearing, An oil pump for supplying oil to a bearing or the like is provided.

  Here, when the refrigerant is dissolved in the lubricating oil, the viscosity of the oil decreases or cavitation occurs, and the lubricating property of the lubricating oil deteriorates. This becomes a problem particularly when a refrigerant having high solubility in oil such as Freon is used as the refrigerant. Thus, in order to make it difficult to dissolve the refrigerant in the lubricating oil, it is preferable that the pressure in the oil tank be as low as possible.

  In addition, when so-called oil rise occurs in which the lubricating oil that lubricates sliding parts such as bearings enters the refrigerant system, the amount of oil in the oil tank becomes insufficient and lubrication abnormality occurs, so the lubricating oil returns to the oil tank. As shown, the oil tank is preferably at the lowest pressure in the turbo compressor.

  For this reason, a general turbo compressor is provided with a pressure equalizing pipe that communicates the oil tank and the downstream side of the suction capacity control unit, which is a low pressure portion in the turbo compressor.

On the other hand, when the turbo chiller is started, the suction capacity control unit is generally limited to the minimum opening for reducing the starting torque. In addition, since the turbo chiller is generally stopped after the capacity control accompanying the decrease in the chilled water temperature, the turbo compressor is stopped while the suction capacity control unit is fully closed, or the turbo compressor In many cases, the suction volume control unit is controlled to be fully closed immediately after stopping.
JP 7-2181010 A

  By the way, during the operation of the turbo refrigerator, the condenser is in a high pressure state due to the high temperature and high pressure refrigerant gas, while the evaporator is in a low pressure state due to the low temperature and low pressure refrigerant liquid. Therefore, when the operation of the turbo chiller is stopped, the refrigerant flows backward from the high pressure condenser side to the low pressure evaporator side, and when the suction capacity control unit is fully closed as shown in FIG. The downstream side of the control unit becomes high pressure. Then, the oil tank communicating with the downstream side of the suction capacity control unit by the pressure equalizing pipe also becomes high pressure.

  On the other hand, the back pressure portion of the impeller, which is slightly lower than the surrounding refrigerant pressure due to the centrifugal force generated by the rotation of the impeller, is lower than the oil tank. Further, since the motor chamber in which the electric motor of the turbo compressor is accommodated communicates with the evaporator, the pressure rise when the operation of the turbo chiller is stopped is moderate, and the pressure is lower than that of the oil tank. Even after the operation of the centrifugal chiller is stopped, lubrication oil continues to be fed in accordance with the inertial rotation of the impeller, and this pressure difference causes so-called oil rise that reaches the pressure equalizing pipe and is sucked into the refrigerant system. There is a problem of end.

  The present invention has been made in view of the above points, and the object of the present invention is to suppress the rise of oil by suppressing the pressure increase in the oil tank of the turbo compressor when the operation of the turbo refrigerator is stopped. There is to do.

  To achieve the above object, a turbo refrigerator according to a first aspect of the present invention includes a turbo compressor (21) having an oil tank (36) for storing lubricating oil, and a refrigerant passing through the turbo compressor (21). A suction capacity control unit (46) for controlling the capacity, and a pressure equalizing pipe (a pressure equalizing pipe) that communicates between the suction capacity control unit (46) and the compression mechanism (12) of the turbo compressor (21) and the oil tank (36). 48), a control unit (50) for controlling at least the operation of the turbo compressor (21) and the opening of the suction capacity control unit (46). (50) opens the suction capacity control unit (46) when the operation of the turbo compressor (21) is stopped.

  According to the above configuration, when the operation of the turbo compressor (21) is stopped, the suction capacity control unit (46) is opened, so that even if the refrigerant flows backward from the condenser side, the suction capacity control unit ( As compared with the case where 46) is in the fully closed state, the pressure increase on the downstream side of the suction capacity control section (46) can be suppressed. Note that when the refrigerant flows backward, the upstream and downstream are also reversed, but here, the compression mechanism side of the suction capacity control unit (46) is the downstream.

  A turbo chiller according to a second aspect of the present invention is the turbo chiller according to the first aspect of the present invention, wherein the control unit (50) is configured to operate the suction capacity control unit when the operation of the turbo compressor (21) is stopped. Control to set the opening of (46) as the target opening is started.

  Here, immediately after the operation of the turbo compressor (21) is stopped, even if the opening of the suction capacity control unit (46) is smaller than the target opening, the operation of the turbo chiller (21) is stopped and the opening direction at that time By starting the control, the pressure rise time of the oil tank (36) can be minimized, and even if an oil rise occurs, it is easy to use with an oil return device, such as an ejector system, that is usually equipped with a turbo refrigerator. To the extent that it is returned to the oil tank (36).

  The target opening is preferably set to the maximum opening from the viewpoint of preventing oil spillage, but since the suction capacity control unit (46) is preferably in a fully closed state at the time of start-up, the control time at the same time as the restart is set. In order to shorten, you may set to the intermediate opening degree of the grade which the oil rise suppression effect is exhibited.

  Further, the opening of the suction volume control unit (46) may be controlled toward the maximum opening when stopped, and may be controlled so as to be fully closed or returned to a predetermined intermediate opening after a predetermined time has elapsed.

  A turbo chiller according to a third aspect of the present invention is the turbo chiller according to the first or second aspect of the invention, wherein the discharge capacity control unit (47) controls the capacity of the refrigerant discharged from the turbo compressor (21). The control unit (50) controls the discharge capacity control unit (47) in the closing direction in which the degree of opening is reduced when the operation of the turbo compressor (21) is stopped.

  According to the above configuration, when an operation stop command arrives at the control unit (50) when attempting to stop the operation of the centrifugal chiller, the control unit (50) first opens the discharge capacity control unit (47). The control is started in the closing direction, and then the operation of the turbo compressor (21) is stopped. When the operation of the turbo compressor (21) is stopped, the opening degree of the discharge capacity control unit (47) is controlled to become smaller, and the refrigerant flowing backward from the condenser is discharged from the discharge capacity control unit (47). Inflow into the turbo compressor (21) is suppressed. Therefore, when the operation of the turbo compressor (21) is stopped, the reverse flow rate of the refrigerant from the condenser side is reduced, so that the pressure increase on the downstream side of the suction capacity control unit (46) is further suppressed.

  According to the first aspect of the invention, since the suction capacity control unit (46) is opened by the control unit (50) when the turbo compressor (21) is stopped, the refrigerant flows backward from the condenser side. As compared with the case where the suction volume control unit (46) is in the fully closed state, the pressure increase on the downstream side of the suction volume control unit (46) is suppressed. For this reason, since the pressure increase in the oil tank (36) communicating with the downstream side of the suction capacity control section (46) can be suppressed by the pressure equalizing pipe (48), the occurrence of oil rising can be suppressed.

  According to the second aspect, the control unit (50) controls the opening of the suction capacity control unit (46) toward the target opening at the same time as the operation of the turbo compressor (21) is stopped. Since the pressure increase on the downstream side of the portion (46) can be suppressed to such an extent that no oil rise occurs, the occurrence of oil rise can be more reliably suppressed.

  According to the third aspect of the invention, when the operation of the turbo compressor (21) is stopped, the opening of the discharge capacity controller (47) is also controlled in the closing direction, so the reverse flow rate of the refrigerant from the condenser side , The pressure increase in the oil tank (36) is further suppressed, and the occurrence of oil rising can be further suppressed.

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

(Structure of refrigerator)
As shown in FIG. 1, a turbo refrigerator (1) according to an embodiment of the present invention includes a turbo compressor (21), an evaporator (26), a condenser (22), an economizer (24), an expansion valve (23 25) and a control unit (50). The operation of the turbo refrigerator (1) is controlled by the capacity control of the turbo compressor (21).

  The turbo compressor (21), which will be described in detail later, includes a compression mechanism (12) having two compression sections (31, 32), and compresses the refrigerant in two stages.

  In the evaporator (26), a tube (27) through which cold water flows is immersed in a refrigerant liquid, and the high-temperature cold water flowing into the evaporator (26) through this tube (27) 26) The heat is deprived within it and cooled, and it flows out as cold water with a low temperature. The refrigerant is evaporated by the heat taken from the cold water by the evaporator (26) to become refrigerant gas, and passes through the low-pressure gas pipe (20) connecting the evaporator (26) and the turbo compressor (21). Sent to (21).

  The condenser (22) is connected to the discharge side of the turbo compressor (21) by a high-pressure gas pipe (28), and includes a tube (29) through which cooling water flows. The high-temperature and high-pressure refrigerant gas that flows from the turbo compressor (21) through the high-pressure gas pipe (28) and into the condenser (22) is deprived of heat by the cooling water flowing in the tube (29) and condensed. Become a liquid.

  The economizer (24) is connected to the condenser (22) by a high stage liquid pipe (13), and the high stage liquid pipe (13) is provided with a high stage expansion valve (23). The high stage expansion valve (23) reduces the high-pressure coolant discharged from the condenser (22) to an intermediate pressure, partially gasifies it, and flows it into the economizer (24). With this gasified refrigerant gas, the remaining liquid refrigerant is supercooled to an intermediate pressure equivalent saturation temperature.

  Further, the economizer (24) is connected to the evaporator (26) by a low stage liquid pipe (14), and the low stage liquid pipe (14) is provided with a low stage expansion valve (25). The low stage expansion valve (25) further reduces the pressure of the refrigerant liquid discharged from the economizer (24) and sends it to the evaporator (26). By this economizer (24), the refrigerant gas and the refrigerant liquid are reliably separated, and wasteful heat loss to the liquid return and hot gas bypass can be prevented.

  The economizer (24) is connected to the turbo compressor (21) by an introduction gas pipe (11). The introduction gas pipe (11) is connected to a communication path (43) between the low-stage compression section (31) and the high-stage compression section (32) in the turbo compressor (21). 43) introduces refrigerant gas. The economizer (24) cools the refrigerant supplied to the evaporator (26) to increase the evaporation capacity, while the refrigerant required for the compression is performed only by the high-stage compression unit (32). ) The overall coefficient of performance can be improved.

(Turbo compressor)
As shown in FIG. 2, the turbo compressor (21) is housed in a sealed container type casing (30), and includes a compression mechanism (12), an electric motor (34), a speed increasing mechanism (33) and an oil. It has a tank (36).

  The casing (30) contains a compression chamber (30a) in which the compression mechanism (12) is accommodated, a motor chamber (30c) in which the electric motor (34) is accommodated, and a speed increasing mechanism (33). The lower part is divided into a central chamber (30b) composed of an oil tank (36).

  The compression mechanism (12) has a low-stage compression section (31) and a high-stage compression section (32) so that the low-stage compression section (31) and the high-stage compression section (32) are adjacent to each other. It is arranged in the compression chamber (30a). The low stage compression section (31) has a low stage impeller (31a), and the high stage compression section (32) has a high stage impeller (32a). These impellers (31a, 32a) are attached to a rotating shaft (35) rotatably supported by a pair of bearings (52, 52).

  The low-pressure gas pipe (20) extending from the evaporator (26) is connected to the low-stage compression section (31) side of the compression chamber (30a), and a suction passage (41) through which refrigerant gas is introduced is formed. ing. The suction path (41) is provided with a suction capacity control unit (46) for controlling the capacity of the refrigerant introduced into the turbo compressor (21). The suction capacity control unit (46) is configured by an inlet guide vane (IGV).

  The low-stage compression section (31) is a spiral low-stage scroll around which the refrigerant gas introduced from the suction capacity control section (46) through the low-stage impeller (31a) passes around the low-stage impeller (31a) It has a chamber (42). The refrigerant gas accelerated by the low stage impeller (31a) passes through the low stage scroll chamber (42), decelerates, and the dynamic pressure is converted into a static pressure.

  On the other hand, the high-stage impeller (32a) that is the suction side of the high-stage compression section (32) and the low-stage scroll chamber (42) that is the discharge side of the low-stage compression section (31) are connected to the communication path (43). It is communicated by. The communication gas passage (43) is connected to the introduction gas pipe (11) extending from the economizer (24), and the economizer ( The low-temperature refrigerant gas from 24) is mixed from the introduction gas pipe (11) and introduced into the high stage compression section (32).

  The high-stage compression section (32) is a spiral high-stage scroll chamber in which the refrigerant gas introduced from the communication path (43) through the high-stage impeller (32a) passes around the high-stage impeller (32a). (44) The refrigerant gas accelerated by the high stage impeller (32a) passes through the high stage scroll chamber (44), decelerates, and the dynamic pressure is converted into a static pressure.

  A high pressure gas pipe (28) connected to the condenser (22) is connected to the discharge side end of the high stage scroll chamber (44), and a discharge path (45) for discharging refrigerant from the turbo compressor (21) Is formed. The discharge path (45) is provided with a discharge capacity control unit (47) for controlling the capacity of the refrigerant discharged from the turbo compressor (21). The discharge capacity control unit (47) controls the discharge capacity of the refrigerant by diffuser control (DDC).

  The rotating shaft (35) is provided so as to pass through the compression chamber (30a), but each through hole prevents the lubricating oil from leaking from the through hole of the compression chamber (30a) and flowing out together with the refrigerant. Are sealed by a labyrinth seal (51).

  The electric motor (34) is disposed in the motor chamber (30c) and functions as a drive source for rotationally driving the compression mechanism (12). The electric motor (34) has an output shaft (34a) rotatably supported by a pair of bearings (53, 53), and the speed increasing mechanism ( 33).

  The motor chamber (30c) is further attached to the inner wall of the casing (30) so as to surround the rotor (34b) and the rotor (34b) which is rotatably integrated between the bearings (53, 53) of the output shaft (34a). And a storage chamber (30d) for storing the stator (34c).

  The speed increasing mechanism (33) has a large gear (33a) and a small gear (33b), and is provided in a central chamber (30b) between the compression chamber (30a) and the motor chamber (30c). Yes. The large gear (33a) is fixed to the output shaft (34a) projecting from the motor chamber (30c) [accommodating chamber (30d)] and projecting into the central chamber (30b). The small gear (33b) is screwed into the large gear (33a) and is fixed to the rotating shaft (35) of the compression mechanism (12) protruding in the central chamber (30b). By this speed increasing mechanism (33), the rotational force of the output shaft (34a) of the electric motor (34) is increased and transmitted to the rotating shaft (35).

  The through holes of the motor chamber (30c) and the storage chamber (30d) of the output shaft (34a) are also sealed by labyrinth seals (54).

  The lower part of the central chamber (30b) is composed of an oil tank (36). The oil tank (36) contains lubricating oil and is provided with an oil pump (37) as an oil supply device for supplying the lubricating oil to the bearings (52, 53). One of the pair of bearings (52, 52) of the rotating shaft (35) of the compression mechanism (12) is provided in the central chamber (30b) [oil tank (36)]. One of the pair of bearings (53, 53) of the output shaft (34a) is also provided in the central chamber (30b) [oil tank (36)].

  The lower part of the motor chamber (30c) in which one of the pair of bearings (53, 53) of the output shaft (34a) is disposed and the oil tank (36) communicate with each other by an oil drain pipe (15). The lubricating oil supplied to the bearing (53) and stored in the lower portion of the motor chamber (30c) is returned to the oil tank (36) through the oil drain pipe (15). The lower part of the storage chamber (30d) and the evaporator (26) are communicated with each other by a refrigerant drain pipe (16), and the refrigerant supplied for cooling the electric motor in the storage chamber (30d) Return to (26).

  The upper part of the central chamber (30b) [oil tank (36)] and the space between the suction capacity control section (46) and the low stage impeller (31a) in the suction passage (41) of the compression chamber (30a) are uniform. It communicates with the pressure pipe (48).

(Control part)
The control unit (50) controls the operation of the turbo compressor (21) and the opening degrees of the suction capacity control unit (46) and the discharge capacity control unit (47).

  When stopping the operation of the turbo chiller (1), the control unit (50) controls the suction capacity control unit (46) toward the target opening.

  Specifically, as shown in FIG. 3, the control unit (50) stops the turbo refrigerator (1), that is, when the operation of the turbo compressor (21) is stopped, the suction capacity control unit ( 46) Start the control to set the opening degree to the target opening degree.

  Here, the target opening is preferably set to the maximum opening from the viewpoint of preventing the oil from rising, but since the suction volume control unit (46) is preferably fully closed at the time of startup, In order to shorten the control time, it may be set to an intermediate opening degree at which the oil rise suppression effect is exhibited.

  In addition, the target opening is set to the maximum opening, and when stopped, the opening of the suction volume control unit (46) is controlled toward the maximum opening, and is fully closed or returned to a predetermined intermediate opening after a certain period of time. You may control as follows.

  Then, when the operation of the turbo compressor (21) is stopped, the control unit (50) controls the opening of the suction capacity control unit (46) and closes the discharge capacity control unit (47) to reduce the opening. Direction control may be initiated.

  Specifically, when a command to stop the turbo chiller (1) is issued, the control unit (50) closes the discharge capacity control unit (47) simultaneously with or before the operation of the turbo chiller (1) is stopped. Is started, the operation of the turbo compressor (21) is stopped, and the control of the suction capacity control unit (46) is started.

  Here, when the operation of the turbo compressor (21) is stopped, if the opening of the discharge capacity control section (47) is too small, the resistance of the discharge capacity control section (47) is excessive with respect to the refrigerant flow rate. This may cause problems such as noise generation. On the other hand, when the operation of the turbo compressor (21) is stopped, the smaller the opening of the discharge capacity control unit (47), the more the refrigerant flows from the high pressure condenser (22) side to the low pressure evaporator (26) side. The backflow is small, and the pressure rise on the downstream side of the suction capacity control unit (46) is also small. Note that when the refrigerant flows backward, the upstream and downstream are also reversed, but here, the compression mechanism side of the suction capacity control unit (46) is the downstream.

  Therefore, the target closing degree of the discharge capacity control unit (47) is such that when the operation of the turbo compressor (21) is stopped, a problem such as noise generation does not occur, and the back flow of the refrigerant is suppressed. Set the opening so that

(Driving operation)
Next, the operation at the time of operation of the turbo refrigerator (1) according to the embodiment of the present invention will be described.

  In the evaporator (26), the refrigerant removes heat from the cold water flowing in the tube (27) and evaporates to flow into the turbo compressor (21) through the low-pressure gas pipe (20) as refrigerant gas. To do.

  The low-pressure refrigerant gas introduced from the suction passage (41) of the turbo compressor (21) flows into the low stage impeller (31a) with the suction capacity controlled by the suction capacity control unit (46). The refrigerant gas that has been compressed by the centrifugal force of the low stage impeller (31a) to become high temperature and high pressure is discharged through the low stage scroll chamber (42) to the communication path (43).

  A refrigerant gas having a low temperature flows into the communication passage (43) from the economizer (24) through the introduction gas pipe (11) and is mixed into the high-temperature refrigerant gas discharged from the low-stage scroll chamber (42). Thus, the temperature of the refrigerant gas introduced into the high stage impeller (32a) decreases.

  The refrigerant gas further compressed by the centrifugal force of the high stage impeller (32a) passes through the high stage scroll chamber (44), the discharge capacity is controlled by the discharge capacity control unit (47), and the high pressure from the discharge path (45). It is discharged into the gas pipe (28).

  The refrigerant gas discharged to the high-pressure gas pipe (28) flows into the condenser (22), is cooled by the cold water flowing through the tube (29), condenses, and becomes a refrigerant liquid.

  The high-pressure refrigerant liquid discharged from the condenser (22) passes through the high-pressure gas pipe (28), is decompressed to an intermediate pressure by the high stage expansion valve (23), and expands. A part of the refrigerant liquid becomes refrigerant gas by the high stage expansion valve (23) and flows into the economizer (24) together with the remaining refrigerant liquid.

  Of the refrigerant that has flowed into the economizer (24), the supercooled refrigerant liquid is discharged to the low-stage liquid pipe (14), and is further decompressed by the low-stage expansion valve (25) and sent to the evaporator (26). On the other hand, among the refrigerant that has flowed into the economizer (24), the refrigerant gas is discharged into the introduction gas pipe (11).

  Next, the operation for stopping the operation of the turbo refrigerator (1) will be described.

  Before the operation of the turbo chiller (1) is stopped, the suction capacity control unit (46) and the discharge capacity control unit (47) are each in an opening state corresponding to the operation state.

  When the control unit (50) receives a command to stop the operation of the turbo chiller (1), the control unit (50) stops the operation of the turbo compressor (21), and the suction capacity control unit (46) The operation is started in the opening direction or the closing direction toward the target opening, and when the target opening is reached, the opening is maintained.

  The discharge capacity control unit (47) may perform control toward the target closing degree at the same time as or before the operation stop of the turbo compressor (21).

  FIG. 3 shows that when the operation of the turbo compressor (21) is stopped, the suction capacity control section (46) is opened when the suction capacity control section (46) is controlled in the opening direction by the control section (50). It is a time chart of degree (IGV opening degree), the high pressure and low pressure (Mpa) of the centrifugal chiller (1), and the pressure (Mpa) on the downstream side of the suction capacity control unit (46).

  Here, immediately after stopping the operation of the turbo compressor (21), even if the opening of the suction capacity control unit (46) is smaller than the target opening, the opening control is performed simultaneously with the stop of the operation of the turbo compressor (21). By starting the oil tank (36), the pressure rise time can be minimized, and even if an oil rise occurs, an oil return device, such as an ejector system, usually provided in a turbo refrigerator Thus, the lubricating oil can be easily suppressed to the extent that it can be returned to the oil tank (36).

(Effect of embodiment)
In the turbo refrigerator (1) of the present embodiment, when the operation of the turbo compressor (21) is stopped by the control unit (50), the opening of the suction capacity control unit (46) is directed toward the target opening. Since the suction capacity control unit (46) is opened when the turbo compressor (21) is stopped, the suction capacity control unit (46) is not fully closed even if the refrigerant flows backward from the condenser side. Compared to a certain case, the pressure increase on the downstream side of the suction capacity control section (46) can be suppressed. For this reason, since the pressure increase in the oil tank (36) communicating with the downstream side of the suction capacity control section (46) can be suppressed by the pressure equalizing pipe (48), the occurrence of oil rising can be suppressed.

  Also, when an operation stop command for the turbo chiller (1) is issued, the control unit (50) causes the turbo compressor (21) when the opening of the discharge capacity control unit (47) reaches the target closing degree. When the operation is stopped, the reverse flow rate of the refrigerant from the condenser side is reduced, the pressure increase in the oil tank (36) is further suppressed, and the occurrence of oil rising can be further suppressed. In addition, the time for reverse rotation operation of the turbo compressor (21) can be shortened.

(Other embodiments)
In addition, the above-mentioned embodiment is an illustration of this invention, Comprising: This invention is not limited to this example. For example, the following configuration may be used.

  That is, in the above embodiment, when the operation of the turbo compressor (21) is stopped, the opening degree of the suction capacity control unit (46) is controlled to be the target opening degree, but it is not necessarily the target opening degree. It does not have to be controlled. When the operation of the turbo compressor (21) is stopped, at least the suction capacity control unit (46) may be left open for a certain period of time without being controlled in the fully closed direction.

  As described above, the present invention is useful for a turbo refrigerator having a turbo compressor.

It is a block diagram of the turbo refrigerator based on embodiment of this invention. It is a longitudinal cross-sectional view of a turbo compressor. It is a time chart which shows the pressure of a turbo refrigerator, and the opening degree of a suction capacity control part. FIG. 4 is a view corresponding to FIG. 3 in a conventional turbo refrigerator.

Explanation of symbols

1 Turbo refrigerator
12 Compression mechanism
21 Turbo compressor
36 Oil tank
46 Suction volume controller
47 Discharge capacity controller
48 Pressure equalizing pipe
50 Control unit

Claims (3)

A turbo compressor (21) having an oil tank (36) for storing lubricating oil, a suction capacity control unit (46) for controlling the capacity of refrigerant passing through the turbo compressor (21), and a suction capacity control unit ( 46) and a turbo chiller comprising a pressure equalizing pipe (48) communicating between the compression mechanism (12) of the turbo compressor (21) and the oil tank (36),
A control unit (50) for controlling at least the operation of the turbo compressor (21) and the opening of the suction capacity control unit (46);
The turbo chiller, wherein when the operation of the turbo compressor (21) is stopped, the control unit (50) opens the suction capacity control unit (46). The turbo chiller according to claim 1,
The turbo refrigeration is characterized in that, when the operation of the turbo compressor (21) is stopped, the control unit (50) starts control to set the opening of the suction capacity control unit (46) as a target opening. Machine. The turbo refrigerator according to claim 1 or 2,
A discharge capacity control section (47) for controlling the capacity of refrigerant discharged from the turbo compressor (21);
When the operation of the turbo compressor (21) is stopped, the control unit (50) controls the discharge capacity control unit (47) in a closing direction in which the opening is reduced. .

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