JP6152062B2 - Centrifugal compressor, turbo refrigerator, supercharger, and control method of centrifugal compressor - Google Patents

Description

  The present invention relates to a centrifugal compressor that compresses a fluid by using an impeller, a turbo refrigerator including the centrifugal compressor, a supercharger, and a control method of the centrifugal compressor.

  The turbo chiller is a large-capacity heat source device that is widely used in applications such as large-scale factory air conditioning having a clean room such as an electric / electronics-related factory and district cooling / heating. A turbo refrigerator is mainly composed of a compressor that compresses refrigerant gas using an impeller, an evaporator, a condenser, and an economizer, and has a type in which refrigerant gas from the economizer flows into the upstream of the second compression stage. Are known.

As the compressor, a centrifugal compressor adopting a two-stage compressor / two-stage expansion cycle is used from the viewpoint of performance and cost (see, for example, Patent Document 1). In order to control the operating range of the centrifugal chiller, the centrifugal compressor is provided with inlet guide vanes (IGVs) for controlling the flow rate upstream of the impeller of the first compression stage and upstream of the impeller of the second compression stage. The angle is changed according to the driving situation.
Some turbo refrigerators are provided with a hot gas bypass pipe from the condenser to the evaporator in order to prevent turning stall.

JP 2011-43130 A

By the way, when operating a centrifugal chiller by partial load operation, a phenomenon is known in which a centrifugal compressor stalls. This occurs when the operating point of the centrifugal compressor becomes a rotation stall generation region, which causes noise of the centrifugal compressor, and also causes shaft vibration when performing high-pressure operation. Although it is possible to perform hot gas bypass from the viewpoint of preventing turning stall, there is a problem in that the performance as a turbo refrigerator decreases due to an increase in the amount of internal circulation.
A vaned diffuser (vaned diffuser) can also be employed to improve the efficiency of the second compression stage, which is less efficient than the first compression stage. However, in partial load operation, the flow angle and vane angle in the diffuser cause a mismatch and the performance is degraded.

  The present invention provides a centrifugal compressor, a turbo refrigerator, a supercharger, and a control method for a centrifugal compressor, in which the occurrence of a turning stall is suppressed and noise and shaft vibration due to the turning stall can be reduced.

According to the first aspect of the present invention, the centrifugal compressor rotates around the axis to discharge the fluid flowing in from the axial direction toward the radially outer side, and introduces the fluid into the impeller. And an inlet guide vane that is provided in the inflow channel and has a plurality of circumferentially spaced intervals and has a variable opening degree, and fluid discharged from the impeller flows. A diffuser, a flow path cross-sectional area adjustment device that makes the flow path cross-sectional area of the diffuser variable, a diffuser vane that is provided in the diffuser, and a plurality of which are arranged at intervals in the circumferential direction and variable in angle. , and a control device for varying the angle of the flow path cross-sectional area, and the diffuser vanes by the inlet guide vanes of the flow path cross-sectional area adjustment device on the basis of the opening degree, the control device, the far A plurality of mechanical Mach number lines indicating the speed of sound of the fluid sucked by the centrifugal compressor are shown on a map displayed by a flow variable reflecting the suction air volume of the compressor and the head of the centrifugal compressor. On the map displayed by the first storage unit storing one characteristic map, the flow rate variable, and the head according to a plurality of mechanical Mach numbers, a turning stall line that becomes a turning stall, and a plurality of inlet guides A second storage unit storing a second characteristic map indicating a vane opening line; and a third storage unit storing a flow angle map indicating a relationship between the flow path cross-sectional area and the flow angle of the fluid in the diffuser. A storage unit; a mechanical Mach number determining unit that calculates the flow variable and the head; and determines a mechanical Mach number of the centrifugal compressor from the first characteristic map; the flow variable and the head; and the mechanical Mach number. A flow rate variable comparison unit that determines an opening degree of the inlet guide vane and a critical flow rate variable in which a rotation stall occurs from the corresponding second characteristic map, and compares the flow rate variable with the flow rate variable comparison unit; In the section, when the flow rate variable is smaller than the critical flow rate variable, the flow path cross-sectional area adjusting device is controlled so that the flow path cross-sectional area decreases, and the flow angle map is used to respond to the flow path cross-sectional area The flow angle is determined, and the angle of the diffuser vane is adjusted according to the flow angle .

  According to the above configuration, when the partial load operation is performed with the inlet guide vane being throttled, and the operating point of the centrifugal compressor is the turning stall generation region, the flow path of the vane-less diffuser using the flow path cross-sectional area adjusting device While reducing the cross-sectional area, the angle of the diffuser vane is changed according to the cross-sectional area of the flow path. As a result, the radial flow velocity in the diffuser increases, the turning angle becomes smaller, and the occurrence of turning stall is suppressed. Further, it is possible to suppress the rotation stall or the back flow of the fluid that occurs in the vane-less portion between the impeller and the diffuser vane. As a result, noise and shaft vibration due to turning stall can be reduced.

  According to the said structure, since a flow-path cross-sectional area and the angle of a diffuser vane can be adjusted more correctly, a performance fall can be suppressed.

  In the present invention, any one of the above centrifugal compressors, a condenser that condenses the refrigerant using the cooling water as a cooling source, and an evaporator that evaporates the refrigerant and cools the cold water are sequentially connected by the refrigerant flow path. To provide a centrifugal chiller having a refrigeration cycle.

  The turbo chiller includes a hot gas bypass pipe that supplies a high-temperature refrigerant gas from the condenser to the evaporator, and the control device includes a flow rate of the high-temperature refrigerant gas flowing into the hot gas bypass pipe, A fourth storage unit storing a first characteristic map showing a relationship with a coefficient of performance of the turbo chiller, a second characteristic showing a relationship between the channel cross-sectional area and the coefficient of performance of the turbo chiller A fifth storage unit storing a map, and when changing the flow rate of the high-temperature refrigerant gas and the flow path cross-sectional area, the amount of decrease in the coefficient of performance accompanying the change in the high-temperature refrigerant gas, and the change in the cross-sectional area of the flow path It is good also as a structure which has the performance fall amount comparison part which compares the fall amount of the coefficient of performance accompanying to and changes only the one with the smaller fall amount among the flow volume of the said high-temperature refrigerant | coolant gas, and the said flow-path cross-sectional area.

  According to the said structure, the rotation stall of a centrifugal compressor can be suppressed, without reducing the performance of a turbo refrigerator significantly.

  Moreover, this invention provides a supercharger provided with one of the said centrifugal compressors.

According to the second aspect of the present invention, the centrifugal compressor control method comprises: an impeller that rotates about an axis and discharges fluid flowing in from the axial direction toward the radially outer side; An inflow channel for introducing a fluid, an inlet guide vane provided in the inflow channel, a plurality of which are arranged at intervals in the circumferential direction and the opening degree of which is variable, and the fluid discharged from the impeller a diffuser but flowing, provided in the diffuser, and the diffuser vanes plurality is disposed angle is varied at intervals in the circumferential direction, a control method of a centrifugal compressor having a suction air amount A parameter calculation step for calculating the reflected flow rate variable and the head of the centrifugal compressor, and determining a plurality of mechanical Mach numbers indicating sound velocity of the fluid sucked by the centrifugal compressor using the flow rate variable and the head. Determining the flow rate variable, the head, the opening degree of the inlet guide vane, and the critical flow rate variable in which the rotation stall occurs by using the mechanical Mach number determination step, and comparing with the flow rate variable A flow rate variable comparison step; and a flow rate cross-sectional area adjustment step of reducing the flow rate cross-sectional area when the flow rate variable is smaller than the limit flow rate variable .

  According to the present invention, when a partial load operation is performed with the inlet guide vane being throttled, and the operating point of the centrifugal compressor is the turning stall generation region, the flow path of the vane-less diffuser using the flow path cross-sectional area adjusting device is used. While reducing the cross-sectional area, the angle of the diffuser vane is changed according to the cross-sectional area of the flow path. As a result, the radial flow velocity in the diffuser increases, the turning angle becomes smaller, and the occurrence of turning stall is suppressed. Further, it is possible to suppress the rotation stall or the back flow of the fluid that occurs in the vane-less portion between the impeller and the diffuser vane. As a result, noise and shaft vibration due to turning stall can be reduced.

It is a schematic block diagram which shows the turbo refrigerator of 1st embodiment of this invention. It is a schematic sectional drawing which shows the centrifugal compressor of 1st embodiment of this invention. It is a disassembled perspective view of the flow-path cross-sectional area adjustment apparatus of 1st embodiment of this invention. It is the 1st characteristic map memorized by the 1st storage part. It is the 2nd characteristic map memorize | stored in the 2nd memory | storage part. It is a flow angle map memorize | stored in the 3rd memory | storage part. It is a flowchart explaining the control method of the centrifugal compressor of 1st embodiment of this invention. It is a map which shows the relationship between the opening degree of a 2nd movable vane, and the flow-path cross-sectional area of a 2nd diffuser. It is a block diagram of the control apparatus of the turbo refrigerator of 2nd embodiment of this invention. It is the 1st coefficient of performance map in which the relationship between the channel cross-sectional area of a 2nd diffuser and the coefficient of performance of a turbo refrigerator was shown. It is the 2nd coefficient of performance map in which the relationship between the flow volume of high temperature refrigerant gas and the coefficient of performance of a turbo refrigerator was shown. It is a flowchart explaining the control method of the centrifugal compressor of 2nd embodiment of this invention. It is a schematic sectional drawing which shows the supercharger of 3rd embodiment of this invention.

(First embodiment)
Hereinafter, the turbo refrigerator 1 provided with the centrifugal compressor 2 of 1st embodiment of this invention is demonstrated in detail with reference to drawings. As shown in FIG. 1, a turbo refrigerator 1 of the present embodiment includes a compressor 2 that compresses a refrigerant, and a condenser 3 that condenses a refrigerant gas, which is a high-temperature and high-pressure fluid compressed by the compressor 2, with cooling water. A subcooler 4 that supercools the liquid-phase refrigerant (liquid refrigerant) condensed in the condenser 3, a high-pressure expansion valve 5 that expands the liquid refrigerant from the subcooler 4, and a high-pressure expansion valve 5. And the economizer 7 (intermediate cooler) connected to the intermediate stage of the compressor 2 and the low-pressure expansion valve 6 evaporates the liquid refrigerant expanded by the low-pressure expansion valve 6 and exchanges heat between the refrigerant and the cold water. And an evaporator 8.
The turbo refrigerator 1 comprises a refrigeration cycle in which a centrifugal compressor 2, a condenser 3, and an evaporator 8 are sequentially connected by a refrigerant flow path. Moreover, the turbo refrigerator 1 is provided with the control apparatus 9 which controls the centrifugal compressor 2 according to the input from each sensor.

The compressor 2 is a centrifugal two-stage compressor, and is driven by an electric motor 11 whose rotation speed is controlled by an inverter that changes an input frequency from a power source.
The subcooler 4 is provided on the downstream side of the refrigerant gas of the condenser 3 so as to supercool the condensed refrigerant.
The condenser 3 and the subcooler 4 are inserted with cooling heat transfer tubes 12 for cooling them, and condensing refrigerant gas using cooling water as a cooling source. A cooling water inlet temperature sensor 13 is provided at the cooling water inlet of the cooling heat transfer tube 12, and a cooling water outlet temperature sensor 14 is provided at the cooling water outlet of the cooling heat transfer tube 12. The outputs of the cooling water inlet temperature sensor 13 and the cooling water outlet temperature sensor 14 are input to the control device 9.

The evaporator 8 is a device that generates a refrigerant gas having a rated temperature (for example, 7 ° C.) by absorbing heat using cold water. A cold water heat transfer tube 15 is inserted into the evaporator 8.
The chilled water heat transfer tube 15 upstream of the evaporator 8 is provided with a chilled water inlet temperature sensor 17 that measures the inlet temperature of the chilled water flowing into the evaporator 8. A cold water outlet temperature sensor 18 that measures the outlet temperature of the cold water that has flowed out of the evaporator 8 is provided at the cold water outlet nozzle downstream of the evaporator 8. The outputs of the cold water inlet temperature sensor 17 and the cold water outlet temperature sensor 18 are input to the control device 9. The cold water heat transfer tube 15 is provided with a cold water flow rate sensor 16 for measuring the flow rate of the cold water.

  A hot gas bypass pipe 24 is provided between the gas phase part of the condenser 3 and the gas phase part of the evaporator 8. The hot gas bypass pipe 24 is provided with a hot gas bypass valve 25 for controlling the flow rate of the high-temperature refrigerant gas flowing through the hot gas bypass pipe 24. The hot gas bypass pipe 24 is provided with a hot gas bypass flow sensor 26 that measures the flow rate of the high-temperature refrigerant gas.

  As shown in FIG. 2, the centrifugal compressor 2 includes an outer casing 28, a rotary shaft 29 that is rotatably supported in the casing 28, and a motor (not shown) that rotationally drives the rotary shaft 29. The first impeller 21 and the second impeller 22 are arranged on the rotary shaft 29 so as to be separated from each other in the axial direction. The first impeller 21 and the second impeller 22 are fixed to a rotating shaft 29, and rotate with the rotation of the rotating shaft 29 to compress the refrigerant gas using centrifugal force.

A suction port 30 through which refrigerant gas flows from the outside is provided on one side in the axial direction of the casing 28, and a scroll 31 that discharges refrigerant gas is provided on the other side in the axial direction. The casing 28 is formed with an internal space 32 that allows the suction port 30 and the scroll 31 to communicate with each other.
The first impeller 21 and the second impeller 22 are disposed in the internal space 32. The first impeller 21 constitutes a first compression stage, and the second impeller 22 constitutes a second compression stage. The internal space 32 includes a return flow path 33 connected to the flow path outlet of the first impeller 21, and a suction flow path 34 (inflow flow path) that connects the return flow path 33 and the second impeller 22.

  The return channel 33 circulates the refrigerant gas from the channel outlet on the radially outer side of the first impeller 21 toward the channel inlet on the radially inner side of the second impeller 22. The return flow path 33 includes a first diffuser 35, a bend portion 36, and a return portion 37. The first diffuser 35 through which the refrigerant gas discharged radially outward from the first impeller 21 is a so-called vaneless diffuser in which no blades (diffuser vanes, blades) are formed.

The first diffuser 35 guides the refrigerant gas compressed by the first impeller 21 and discharged radially outward from the flow path outlet of the first impeller 21 to the radially outer side. A radially outer side of the first diffuser 35 is communicated with a return portion 37 via a bend portion 36.
Return vanes 38 are arranged radially around the entire circumference of the return portion 37 on the downstream side of the bend portion 36.

The refrigerant gas compressed in the second impeller 22 is discharged from the scroll 31 through a second diffuser 39 provided around the second impeller 22. The second diffuser 39 on the downstream side of the second impeller 22 is provided with a diffuser vane 55 in which a plurality of the diffuser vanes 55 are arranged at intervals in the circumferential direction and the angle of which is variable. That is, the second diffuser is a vaned diffuser.
The angle of the diffuser vane 55 can be changed according to the flow angle of the fluid flowing into the second diffuser 39, for example. The diffuser vane 55 is driven by a driving device 56 provided in the centrifugal compressor 2.

The centrifugal compressor 2 is provided with an intermediate suction chamber 40 that joins the refrigerant gas generated by the economizer 7 (see FIG. 1) to the discharge flow of the first impeller 21 and supplies it to the second impeller 22. The intermediate suction chamber 40 is formed as an annular space surrounding the periphery of the inlet portion of the second impeller 22. Refrigerant gas from the economizer 7 is supplied to the intermediate suction chamber.
A slit 41 is provided on the inner peripheral portion of the intermediate suction chamber 40 over the entire periphery, and the inside of the intermediate suction chamber 40 and the return portion 37 of the return flow path 33 are connected.

In addition, a first movable vane 42 (inlet guide vane, IGV) whose angle can be changed in accordance with an operating state is provided at the inlet 30 of the centrifugal compressor 2 and the inlet of the first impeller 21 of the first compression stage. ) Is provided. Further, a second movable vane 43 capable of changing an angle (opening degree) according to an operation state is provided in the suction passage 34 of the return passage 33 and at the inlet of the second impeller 22 of the second compression stage. It has been. A plurality of first movable vanes 42 and second movable vanes 43 are arranged at intervals in the circumferential direction. The centrifugal compressor 2 is provided with a drive device 44 for driving the second movable vane 43.
Further, the second diffuser 39 on the downstream side of the second stage impeller of the centrifugal compressor 2 has a width of the second diffuser 39, that is, a channel cross-sectional area of the second diffuser 39, that is, an axis of the second diffuser 39. A flow path cross-sectional area adjusting device 46 for changing the width in the direction is provided.

  FIG. 3 is an exploded perspective view of the flow path cross-sectional area adjusting device 46. In the assembled channel cross-sectional area adjusting device 46, the width adjusting ring 50 is disposed on the inner peripheral side of the drive ring 49. As shown in FIG. 3, the flow path cross-sectional area adjusting device 46 includes a drive shaft 47 that can be driven in the longitudinal direction by a motor (not shown), a drive ring 49 that is connected to the drive shaft 47 via a bracket 48, and a drive. A width adjusting ring 50 that can be advanced and retracted from the casing 28 by the rotation of the ring 49.

The drive ring 49 is an annular member that is restricted from moving in the axial direction (the direction along the axis of the rotary shaft 29) and can be rotated in the circumferential direction by driving the drive shaft 47.
The width adjusting ring 50 is an annular member that is movable in the axial direction. The width adjustment ring 50 is arranged on the inner peripheral side of the drive ring 49 so that the outer peripheral surface of the width adjustment ring 50 and the inner peripheral surface of the drive ring 49 are slidably in contact with each other. One end in the axial direction of the width adjusting ring 50 is disposed so as to be exposed to the second diffuser 39.

  The drive ring 49 and the width adjustment ring 50 are configured such that the width adjustment ring 50 moves in the axial direction as the drive ring 49 rotates. As a result, one end of the width adjusting ring 50 in the axial direction moves so as to reduce the width of the second diffuser 39.

Returning to FIG. 1, the control device 9 is responsible for overall control of the turbo chiller 1, a mechanical Mach number determining unit 61 that determines the mechanical Mach number (rotation number) of the turbo chiller 1, and the centrifugal compressor 2. And a flow rate variable comparison unit 62 for determining whether or not the flow rate variable θ reflecting the suction air volume is a flow rate variable in which a turning stall occurs.
Further, the control device 9 is configured so that the centrifugal compressor 2 is placed on a map displayed by a flow variable θ reflecting the suction air volume of the centrifugal compressor 2 and the head H of the centrifugal compressor 2 as shown in FIG. It has the 1st memory | storage part 63 which memorize | stored the 1st characteristic map 65 in which the several mechanical Mach number line which shows the sound speed of the refrigerant | coolant gas to inhale was shown. The first characteristic map 65 is created in advance by carrying out an operation test of the centrifugal compressor 2 in advance. On the map with the horizontal axis representing the flow variable θ and the vertical axis representing the head H, the turning stall line L And a plurality of mechanical Mach number lines. In the present embodiment, the first characteristic map 65 is a map in which the opening degree of the first movable vane 42 is 100%, which is the maximum opening degree.

In addition, the control device 9 has a turning stall line L, which is a turning stall, on a map displayed by the flow rate variable θ and the head H in accordance with a plurality of mechanical Mach numbers as shown in FIG. The second storage unit 64 stores a second characteristic map 66 showing the inlet guide vane opening degree line.
The second characteristic map 66 shows a turning stall line L and a plurality of inlet guide vane opening lines on a map in which the horizontal axis represents a flow variable θ and the vertical axis represents a head H. This inlet guide vane opening degree line indicates the opening degree of the second movable vane 43. In the second characteristic map 66, the region below the turning stall line L is a stable region S that does not cause turning stall or surging, and the region above the turning stall line L is subject to turning stall or surging. The unstable region NS is caused.

  Further, the control device 9 stores a flow angle map 67 in which the relationship between the flow path cross-sectional area of the second diffuser 39 and the flow angle of the refrigerant gas in the second diffuser as shown in FIG. 6 is stored. Has a part. The flow angle map 67 shown in FIG. 6 indicates that the flow angle of the refrigerant gas increases as the flow path cross-sectional area increases.

The mechanical Mach number determining unit 61 calculates the flow variable θ and the head H, and determines the mechanical Mach number M of the centrifugal compressor 2 from the first characteristic map 65.
The flow rate variable comparison unit 62 determines the opening of the second movable vane 43 and the limit flow rate variable θrs that causes the rotation stall from the flow rate variable θ, the head H, and the second characteristic map 66 corresponding to the mechanical Mach number M. And compare with the flow variable θ.

Next, the control method of the turbo refrigerator 1 of this embodiment is demonstrated with reference to the flowchart shown in FIG.
(Parameter calculation step S1)
The control device 9 performs centrifugal compression using the cold water flow rate measured by the cold water flow sensor 16, the cold water inlet temperature measured by the cold water inlet temperature sensor 17, and the cold water outlet temperature measured by the cold water outlet temperature sensor 18. A flow variable θ reflecting the suction air volume of the machine 2 is calculated.
Further, the control device 9 calculates the head H using the cooling water inlet temperature measured by the cooling water inlet temperature sensor 13 and the cooling water outlet temperature measured by the cooling water outlet temperature sensor 14.

(Mechanical Mach number determination step S2)
Next, the machine Mach number determination unit 61 of the control device 9 determines the machine Mach number M using the first characteristic map 65 stored in the first storage unit 63.
Specifically, the flow rate variable θ and the head H are plotted on the first characteristic map 65 (indicated by reference symbol P in FIG. 4).
When the electric motor 11 has an inverter, if the plot point P is an operating point below the turning stall line L, the Mach number M, which is the point P, is adjusted, so that the Mach number M is operated at an IGV of 100%. . If the operating point is above the turning stall line L, the Mach number M on the right side of the point P is selected (an arbitrary Mach number M can be selected).
On the other hand, in a machine having a constant rotation speed (fixed speed machine), the operation is performed with the IGV reduced by a Mach number M corresponding to the rotation speed determined by the gear. The operation that may require the diffuser throttling is an operation point where the head H is smaller on the smaller flow rate side than the rated point, so that the partial load operation of the fixed speed machine is always the operation with the IGV throttled.

(Flow rate variable comparison step S3)
Next, the flow rate variable comparison unit 62 of the control device 9 compares the flow rate variable θ using the second characteristic map 66 stored in the second storage unit 64. Specifically, the flow rate variable θ and the head H are plotted on the second characteristic map 66 (indicated by the symbol P in FIG. 5), and the opening degree of the second movable vane 43 is determined. For example, according to the plot point P shown in FIG. 5, the opening degree of the second movable vane 43 is 70%.
Next, the flow rate variable comparison unit 62 determines a limit point PL at which no turning stall occurs at the opening degree 70% of the second movable vane 43, and sets the flow rate variable θ at this limit point as the limit flow rate variable θrs. Then, the flow rate variable θ calculated in the parameter calculation step is compared with the limit flow rate variable θrs.
When the flow rate variable θ is larger than the limit flow rate variable θrs, the control device 9 does not adjust the flow path cross-sectional area of the second diffuser 39 (step S4).

On the other hand, when the flow rate variable θ is smaller than the limit flow rate variable θrs, the control device 9 calculates the flow path cross-sectional area that suppresses the occurrence of the turning stall (step S5).
Next, the control device 9 adjusts the channel cross-sectional area of the second diffuser 39 using the channel cross-sectional area adjusting device 46 (channel cross-sectional area adjusting step S6). Specifically, the control device 9 performs adjustment in a direction in which the flow path cross-sectional area decreases. Thereby, the radial flow velocity in the second diffuser 39 is increased, the turning speed is reduced, and the occurrence of turning stall is suppressed.
As shown in FIG. 8, the opening degree of the second movable vane 43 and the cross-sectional area of the flow path of the second diffuser 39 are compiled into a database, and the flow path breakage of the second diffuser 39 according to the rotation of the second movable vane 43. The area may be changed.

  Next, the control device 9 determines the flow angle of the refrigerant gas corresponding to the flow path cross-sectional area of the second diffuser 39 using the flow angle map 67 stored in the third storage unit 69. Then, the angle of the diffuser vane 55 is changed according to the flow angle of the refrigerant gas (channel cross-sectional area adjustment step S7).

  According to the above embodiment, when the partial load operation is performed with the second movable vane 43 constricted, and the operating point of the centrifugal compressor 2 is the turning stall generation region, the flow path cross-sectional area adjusting device 46 is used to While reducing the channel cross-sectional area of the two diffusers 39, the angle of the diffuser vane 55 is changed according to the channel cross-sectional area. Thereby, the radial flow velocity in the second diffuser 39 is increased, the turning angle is reduced, and the occurrence of turning stall is suppressed. Further, it is possible to suppress the rotating stall or the back flow of the fluid that occurs in the vaneless portion between the second impeller 22 and the diffuser vane 55. As a result, noise and shaft vibration due to turning stall can be reduced.

Further, by determining the mechanical Mach number M using the first characteristic map 65 and determining the critical flow rate variable θrs that causes the rotation stall using the second characteristic map 66, the flow path cross-sectional area can be more accurately determined. Since it can be adjusted, it is possible to suppress a decrease in performance due to excessive restriction of the flow path cross-sectional area.
Moreover, since the angle of the diffuser vane 55 can be adjusted more accurately by changing the angle of the diffuser vane 55 using the flow angle map 67, it is possible to suppress performance degradation.

  The structure of the flow path cross-sectional area adjusting device 46 is not limited to that shown in the above embodiment. For example, the structure of the flow path cross-sectional area adjusting device 46 may be configured to drive the width adjusting ring 50 using an actuator such as a hydraulic cylinder without using the driving shaft 47 and the driving ring 49.

(Second embodiment)
Hereinafter, the turbo refrigerator 1 provided with the centrifugal compressor 2 of 2nd embodiment of this invention is demonstrated based on drawing. In the present embodiment, differences from the first embodiment described above will be mainly described, and description of similar parts will be omitted.
The control device 9B of the centrifugal compressor 2 according to the present embodiment is characterized by performing control in consideration of the flow rate of the high-temperature refrigerant gas flowing into the hot gas bypass pipe 24.
As shown in FIG. 9, the control device 9 </ b> B according to the present embodiment changes the flow rate of the high-temperature refrigerant gas introduced into the hot gas bypass pipe 24 and the flow passage cross-sectional area of the second diffuser 39. A coefficient of performance comparison unit 68 that compares the amount of decrease in the coefficient of performance accompanying the change in the flow rate with the amount of decrease in the coefficient of performance associated with the change in the channel cross-sectional area.

Further, the control device 9B stores a first coefficient of performance map 71 in which the relationship between the channel cross-sectional area of the second diffuser 39 and the coefficient of performance COP of the turbo chiller 1 is shown, as shown in FIG. There are four storage units 70.
Further, the control device 9B, as shown in FIG. 11, shows a second coefficient of performance map 72 showing the relationship between the flow rate of the high-temperature refrigerant gas introduced into the hot gas bypass pipe 24 and the coefficient of performance COP of the turbo chiller 1. Has a fifth storage unit 73 stored therein.

  Next, the control method of the turbo refrigerator 1 of this embodiment is demonstrated with reference to the flowchart shown in FIG. Steps S1B to S4B in this flowchart are the same as steps S1 to S4 of the first embodiment, and thus description thereof is omitted.

(Calculation amount decrease step S5B associated with change in flow path cross-sectional area)
The control device 9B refers to the first coefficient of performance map 71 stored in the third storage unit 69, and when the flow passage cross-sectional area of the second diffuser 39 is changed, the coefficient of decrease Δη1 (efficiency decrease) , See FIG. 9).

(Step of calculating decrease in coefficient of performance associated with hot gas bypass S6B)
The control device 9B refers to the second coefficient of performance map 72 stored in the fourth storage unit 70, and when the high-temperature refrigerant gas is introduced into the hot gas bypass pipe 24, the coefficient of decrease Δη2 (efficiency decrease) , See FIG. 10).

(Coefficient of performance comparison process S7B)
The coefficient of performance comparison unit 68 of the control device 9B compares the reduction amount Δη1 with the reduction amount Δη2. That is, it is determined which of the cases where the coefficient of performance is further reduced between the case where the cross-sectional area of the second diffuser 39 is changed and the case where the hot gas bypass is performed.
If the reduction coefficient Δη1 of the coefficient of performance COP when the flow passage cross-sectional area of the second diffuser 39 is changed is larger, the control device 9B performs the turning stall suppression with the hot gas bypass (step S8B).
On the other hand, when the decrease amount Δη2 of the coefficient of performance when performing hot gas bypass is larger, the control device 9B performs turning stall suppression by adjusting the flow path cross-sectional area of the second diffuser 39 (step S9B).
Next, the control device 9 </ b> B determines the flow angle of the refrigerant gas corresponding to the flow path cross-sectional area of the second diffuser 39 using the flow angle map 67 stored in the third storage unit 69. Then, the angle of the diffuser vane 55 is changed according to the flow angle of the refrigerant gas (step S10B).

  According to the above embodiment, the rotation stall of the centrifugal compressor 2 can be suppressed without greatly reducing the coefficient of performance of the turbo refrigerator 1.

(Third embodiment)
Hereinafter, the supercharger 10 provided with the centrifugal compressor 2C of 3rd embodiment of this invention is demonstrated based on drawing. In the present embodiment, differences from the first embodiment described above will be mainly described, and description of similar parts will be omitted.
As shown in FIG. 12, the turbocharger 10 including the centrifugal compressor 2 </ b> C of the present embodiment includes a casing 28 that forms an outer shell, a rotating shaft 29, and an impeller 21, and from the outside of the casing 28. Compresses introduced fluids such as gas and air.

A suction port 30 for allowing fluid to flow in from the outside is provided on one side in the axial direction of the casing 28, and a scroll 31 for discharging the fluid is provided on the other side in the axial direction.
A movable vane 42 whose angle can be changed according to the operating condition is provided at the inlet 30 of the supercharger and at the inlet of the impeller 21.

The diffuser 39 on the downstream side of the impeller 21 is provided with a diffuser vane 55 in which a plurality are arranged at intervals in the circumferential direction and the angle is variable. The diffuser vane 55 is driven by a driving device 56 provided in the supercharger 10.
The diffuser 39 on the downstream side of the impeller 21 of the supercharger 10 is provided with a flow path cross-sectional area adjusting device 46 that changes the axial width of the diffuser 39.

  The supercharger 10 includes a control device similar to the centrifugal compressor 2 of the first embodiment or the second embodiment. That is, the supercharger 10 performs a partial load operation with the movable vane 42 throttled, and when the operating point of the supercharger 10 is in the turning stall generation region, the diffuser 39 using the flow path cross-sectional area adjusting device 46. And the angle of the diffuser vane 55 is changed according to the channel cross-sectional area. Thereby, the radial flow velocity in the diffuser 39 is increased, the turning angle is reduced, and the occurrence of turning stall is suppressed. Further, it is possible to suppress the rotating stall or the back flow of the fluid that occurs in the vane-less portion between the impeller 21 and the diffuser vane 55. As a result, noise and shaft vibration due to turning stall can be reduced.

  Although the embodiments of the present invention have been described in detail with reference to the drawings, the configurations and combinations of the embodiments in the embodiments are examples, and the addition and omission of configurations are within the scope not departing from the gist of the present invention. , Substitutions, and other changes are possible. Further, the present invention is not limited by the embodiments, and is limited only by the scope of the claims.

DESCRIPTION OF SYMBOLS 1 Turbo refrigerator 2 Compressor 3 Condenser 4 Subcooler 5 High-pressure expansion valve 6 Low-pressure expansion valve 7 Economizer 8 Evaporator 9 Controller 10 Supercharger 11 Electric motor 12 Cooling heat transfer tube 13 Cooling water inlet temperature sensor 14 Cooling water outlet temperature Sensor 15 Chilled water heat transfer pipe 16 Chilled water flow rate sensor 17 Chilled water inlet temperature sensor 18 Chilled water outlet temperature sensor 21 First impeller 22 Second impeller (impeller)
24 Hot gas bypass pipe 25 Hot gas bypass valve 26 Hot gas bypass flow sensor 28 Casing 29 Rotating shaft 30 Suction port 31 Scroll 32 Internal space 33 Return flow path 34 Suction flow path (inflow flow path)
35 First diffuser 36 Bend part 37 Return part 38 Return vane 39 Second diffuser (diffuser)
40 Intermediate suction chamber 42 First movable vane 43 Second movable vane (inlet guide vane)
44 Drive device 46 Flow path cross-sectional area adjustment device 47 Drive shaft 48 Bracket 49 Drive ring 50 Width adjustment ring 52 Ring drive groove 55 Diffuser vane 56 Drive device 61 Mechanical Mach number determination unit 62 Flow rate variable comparison unit 63 First storage unit 64 First Two storage parts 65 First characteristic map 66 Second characteristic map 67 Flow angle map 68 Performance coefficient comparison part (performance degradation amount comparison part)
69 Third memory section 70 Fourth memory section 71 First coefficient of performance map 72 Second coefficient of performance map 73 Fifth memory section H Head M Machine Mach number θ Flow rate variable θrs Limit flow rate variable

Claims (6)

An impeller that rotates around an axis and discharges fluid flowing in from the axial direction toward the radially outer side;
An inflow channel for introducing the fluid into the impeller;
An inlet guide vane provided in the inflow channel, a plurality of which are arranged at intervals in the circumferential direction and whose opening is variable;
A diffuser through which the fluid discharged from the impeller flows;
A flow path cross-sectional area adjusting device that makes the flow path cross-sectional area of the diffuser variable;
A diffuser vane provided in the diffuser, a plurality of which are arranged at intervals in the circumferential direction and the angle of which is variable;
Wherein a the inlet guide the flow path cross-sectional area by the flow path cross-sectional area adjustment device based on the opening degree of the vane, and a control device for varying the angle of the diffuser vane, centrifugal compressor Ru provided with,
The controller is
A plurality of mechanical Mach number lines indicating the speed of sound of the fluid sucked by the centrifugal compressor are shown on a map displayed by a flow variable reflecting the suction air volume of the centrifugal compressor and the head of the centrifugal compressor. A first storage unit storing the first characteristic map;
A second characteristic map showing a turning stall line and a plurality of inlet guide vane opening lines on a map displayed by the flow rate variable and the head according to a plurality of machine Mach numbers. A second storage unit storing
A third storage unit storing a flow angle map showing a relationship between the flow path cross-sectional area and the flow angle of the fluid in the diffuser;
Calculating the flow rate variable and the head, and determining a mechanical Mach number determination unit of the centrifugal compressor from the first characteristic map;
From the second characteristic map corresponding to the flow variable and the head and the mechanical Mach number, the opening degree of the inlet guide vane and a critical flow variable in which turning stall occurs are determined and compared with the flow variable. A variable comparison unit,
In the flow rate variable comparison unit, when the flow rate variable is smaller than the limit flow rate variable, the flow path cross-sectional area adjustment device is controlled so that the flow path cross-sectional area decreases,
A centrifugal compressor , wherein a flow angle corresponding to the flow path cross-sectional area is determined using the flow angle map, and an angle of the diffuser vane is adjusted according to the flow angle . A centrifugal compressor according to claim 1 ;
A condenser that condenses refrigerant using cooling water as a cooling source;
A turbo chiller comprising a refrigeration cycle in which an evaporator that evaporates a refrigerant and cools cold water is sequentially connected by a refrigerant flow path.   An impeller that rotates around an axis and discharges fluid flowing in from the axial direction toward the radially outer side;
  An inflow channel for introducing the fluid into the impeller;
  An inlet guide vane provided in the inflow channel, a plurality of which are arranged at intervals in the circumferential direction and whose opening is variable;
  A diffuser through which the fluid discharged from the impeller flows;
  A flow path cross-sectional area adjusting device that makes the flow path cross-sectional area of the diffuser variable;
  A diffuser vane provided in the diffuser, a plurality of which are arranged at intervals in the circumferential direction and the angle of which is variable;
  A centrifugal compressor comprising: a control device that changes the flow passage cross-sectional area and the angle of the diffuser vane by the flow passage cross-sectional area adjustment device based on the opening of the inlet guide vane;
  A condenser that condenses the refrigerant using cooling water as a cooling source,
  A turbo chiller in which a refrigeration cycle is configured by sequentially connecting an evaporator that evaporates a refrigerant to cool cold water and a refrigerant flow path;
  A hot gas bypass pipe for supplying high-temperature refrigerant gas from the condenser to the evaporator;
  The controller is
A fourth storage unit storing a first characteristic map showing a relationship between a flow rate of the high-temperature refrigerant gas flowing into the hot gas bypass pipe and a coefficient of performance of the turbo refrigerator;
  A fifth storage unit storing a second characteristic map showing a relationship between the flow path cross-sectional area and the coefficient of performance of the turbo refrigerator;
  When changing the flow rate of the high-temperature refrigerant gas and the cross-sectional area of the flow path, the amount of decrease in the coefficient of performance accompanying the change in the high-temperature refrigerant gas is compared with the amount of decrease in the coefficient of performance accompanying the change in the cross-sectional area of the flow path And a performance reduction amount comparison unit that changes only a smaller one of the flow rate of the high-temperature refrigerant gas and the flow path cross-sectional area.   The controller is
  A plurality of mechanical Mach number lines indicating the speed of sound of the fluid sucked by the centrifugal compressor are shown on a map displayed by a flow variable reflecting the suction air volume of the centrifugal compressor and the head of the centrifugal compressor. A first storage unit storing the first characteristic map;
  A second characteristic map showing a turning stall line and a plurality of inlet guide vane opening lines on a map displayed by the flow rate variable and the head according to a plurality of machine Mach numbers. A second storage unit storing
  A third storage unit storing a flow angle map showing a relationship between the flow path cross-sectional area and the flow angle of the fluid in the diffuser;
  Calculating the flow rate variable and the head, and determining a mechanical Mach number determination unit of the centrifugal compressor from the first characteristic map;
  From the second characteristic map corresponding to the flow variable and the head and the mechanical Mach number, the opening degree of the inlet guide vane and a critical flow variable in which turning stall occurs are determined and compared with the flow variable. A variable comparison unit,
  In the flow rate variable comparison unit, when the flow rate variable is smaller than the limit flow rate variable, the flow path cross-sectional area adjustment device is controlled so that the flow path cross-sectional area decreases,
  4. The turbo refrigerator according to claim 3, wherein a flow angle corresponding to the flow path cross-sectional area is determined using the flow angle map, and an angle of the diffuser vane is adjusted according to the flow angle. A turbocharger comprising the centrifugal compressor according to claim 1 . An impeller that rotates around an axis and discharges fluid flowing in from the axial direction toward the radially outer side;
An inflow channel for introducing the fluid into the impeller;
An inlet guide vane provided in the inflow channel, a plurality of which are arranged at intervals in the circumferential direction and whose opening is variable;
A diffuser through which the fluid discharged from the impeller flows;
A control method of a centrifugal compressor having a diffuser vane provided in the diffuser and having a plurality of circumferentially spaced intervals and a variable angle,
A parameter calculation step for calculating a flow variable reflecting the suction air volume and a head of the centrifugal compressor;
A mechanical Mach number determining step for determining a plurality of mechanical Mach numbers indicating sound speeds of the fluid sucked by the centrifugal compressor using the flow variable and the head;
A flow rate variable comparison step of determining the opening amount of the inlet guide vane using the flow rate variable and the head, and the mechanical Mach number, a limit flow rate variable in which a turning stall occurs, and comparing the flow rate variable;
A flow path cross-sectional area adjustment step of changing the flow path cross-sectional area of the diffuser and the angle of the diffuser vane based on the opening of the inlet guide vane, where the flow variable is smaller than the limit flow variable, And a flow path cross-sectional area adjustment step for reducing the flow path cross-sectional area .

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