DE112015006203T5 - compressor system - Google Patents

Abstract

A compressor system (10) includes a motor (3) having a rotor (31) configured to rotate about an axis, and a stator (32) disposed on an outer peripheral side of the rotor (31). a compressor (2) having an impeller (22) configured to compress a working fluid (31) by co-rotating with the rotor, and a housing (23) covering the impeller (22) from an outer peripheral side ; and a heat exchange flow path (600) through which a fluid is flowed inside the stator (32) or in a gap between the stator (32) and the rotor (31) and heat is exchangeable between the fluid and the housing (23).

Description

Technical area

The present invention relates to a compressor system.

The priority of Japanese Patent Application No. 2015-032803 filed Feb. 23, 2015, the contents of which are incorporated herein by reference.

State of the art

A compressor system in which a motor and a compressor are integrated includes a compressor for compressing a gas such as air or the like and a motor for driving the compressor. In the compressor system, a rotary shaft extending from a housing of the compressor and a rotary shaft of the motor similarly extending from a housing of the engine are connected. The rotation of the engine is transferred to the compressor. The rotary shafts of the engine and the compressor are supported by a plurality of bearings and thus rotate reliably.

Such a compressor system is used, for example, for an underwater production system as in Non-Patent Document 1 or as a Floating Production Storage and Discharge Unit (FPSO) as in Non-Patent Document 2. When the compressor system is used for the subsea production system, the compressor system is installed in the seabed. The compressor system transmits production fluids mixed with crude oils and natural gases drawn from production wells drilled into the ocean floor to a depth of several thousand meters to the sea surface. When the compressor system is used for the FPSO unit, the compressor system is installed in a marine facility such as a ship.

CITATION

Non-patent literature

Non-Patent Document 1

• Mitsubishi Heavy Industries Technical Review Vol. 34 No. 5 S310-S313

Non-patent document 2

• Turbomachinery International September / October 2014 P18-P24

Presentation of the invention

Technical task

Incidentally, the temperatures of the components constituting the compressor, such as an impeller and a casing, when a compressor of a compressor system is stopped or normally operated, are different. In particular, in the impeller and the housing, the degree of temperature changes, when activated or stopped, is different due to a high volume difference of the elements. Therefore, since a temperature difference between the impeller and the housing becomes larger in accordance with the operating conditions of the compressor system, the amount of thermal expansion greatly varies and the distance between the impeller and the housing varies. As a result, there is a possibility that a clearance between the impeller and the housing is excessively narrowed and the impeller and the housing come into contact with each other while the compressor system is activated or stopped.

The present invention provides a compressor system in which a space between an impeller and a housing can be prevented from being excessively narrowed.

Solution of the task

In order to address the above objects, the present invention proposes the following solutions.

A compressor system according to a first aspect of the present invention includes a motor having a rotor configured to rotate about an axis and a stator disposed on an outer peripheral side of the rotor; a compressor having an impeller configured to compress a working fluid by rotating together with the rotor, and a housing covering the impeller from an outer peripheral side; and a heat exchange flow path through which fluid flowing in the stator or in a gap between the stator and the rotor is circulated and heat is exchangeable between the fluid and the housing.

In such an embodiment, the temperature of the flowing inside the stator or in a gap between the stator and the rotor fluid is increased by cooling the stator and the rotor. The fluid, the temperature of which has increased, exchanges heat with the housing through the heat exchange flow path to the Heat housing efficiently and quickly. As a result, after a temperature change in the impeller when the compressor system is activated or stopped, the housing can be heated quickly. Therefore, it is possible to reduce the difference between an amount of thermal expansion of the impeller and an amount of thermal expansion of the casing.

In a compressor system according to a second aspect of the present invention, in the first aspect, the fluid may be a working fluid which is compressed by the impeller.

In such an embodiment, the rotor and the stator may be cooled by the working fluid, the temperature of which has increased as it is compressed by the impeller. As a result, the working fluid can be further heated and supplied to the housing. Therefore, it is possible to heat the case effectively.

In a compressor system according to a third aspect of the present invention, in the first or second aspect, a flow rate adjustment unit configured to adjust a flow rate of the fluid circulating in the heat exchange flow path may be included when a temperature difference between the housing and the impeller is a requirement predetermined reference fulfilled.

In such a configuration, when the temperature difference between the housing and the impeller satisfies a requirement of a predetermined reference, the flow rate of the fluid is adjusted by the fluid adjusting unit. Therefore, only a necessary amount of the fluid can be circulated in the heat exchange flow path. Therefore, for example, if the temperature difference between the housing and the impeller is small and there is no need to heat the housing, it is possible to prevent the fluid from being continuously circulated in the heat exchange flow path. Therefore, it is possible to efficiently circulate the fluid in the heat exchange flow path.

Advantageous Effects of the Invention

According to the compressor system of the present invention, it is possible to heat the housing using the fluid whose temperature has increased when the rotor and the stator are cooled. As a result, it can be prevented that a clearance between the impeller and the housing is excessively narrowed.

Short description of the figures

1 FIG. 10 is a schematic drawing showing a compressor system according to a first embodiment of the present invention. FIG.

2 Fig. 10 is a schematic drawing showing a compressor system according to a second embodiment of the present invention.

3 Fig. 10 is a schematic drawing showing a compressor system according to a third embodiment of the present invention.

4 FIG. 10 is a schematic drawing showing a compressor system according to a fourth embodiment of the present invention. FIG.

Description of embodiments

First embodiment

A first embodiment according to the present invention will be described below with reference to FIG 1 described.

A compressor system 10 is intended for use in the seafloor for an underwater production system suitable for ocean oil and gas field closure and intended for use on the sea surface for a floating production storage and unloading unit (FPSO). The compressor system 10 supplies pressure to a production fluid, such as For example, oils and gases derived from oil-gas field production wells located several hundreds to thousands of meters from the seabed are employed as working fluid.

As in 1 is shown, the compressor system 10 a compressor 2 , a motor 3 , a warehouse 4 , a housing 5 , a heat exchange flow path 600 and a flow rate adjustment unit 7 on. The compressor 2 has a wave 21 extending in an O-axis direction (in a horizontal direction in FIG 1 ) as a rotation shaft. The motor 3 has a rotor 31 on that directly with the shaft 21 connected is.

The warehouse 4 supports the wave 21 , The housing 5 takes the engine 3 and the compressor 2 on. In the heat exchange flow path 600 occurs heat exchange with a circulating fluid, and thus becomes a housing 23 of the compressor 2 heated. The flow rate adjustment unit 7 Sets the flow rate of a fluid in the heat exchange flow path 600 circulated.

The compressor 2 is inside the case 5 arranged. The compressor 2 compresses a working fluid when the shaft 21 around an O-axis together with the rotor 31 rotates. The compressor 2 this embodiment has the shaft 21 , an impeller 22 and the case 23 on. The wave 21 extends in the direction of the O-axis. The impeller 22 is on an outer peripheral surface of the shaft 21 attached and rotates together with the rotor 31 to thereby compress a working fluid. The housing 23 covers the wheel 22 from the outside.

The wave 21 is a rotation shaft that extends in the O-axis direction. The wave 21 gets from the case 5 supported to be rotatable about the O-axis. The wave 21 penetrates the housing 23 in the direction of the O-axis. The wave 21 has ends that are both from the housing 23 extend. The wave 21 extends in the O-axis direction in the housing 5 which will be described below.

The impeller 22 rotates together with the shaft 21 and compresses a working fluid passing through the interior of the impeller 22 passes through to produce a compressed fluid. A plurality of wheels 22 is on the outer peripheral surface of the shaft 21 attached side by side with spaces therebetween in the O-axis direction.

The housing 23 is an outside of the compressor 2 , The housing 23 takes the wheel 22 in it. The housing 23 is inside the case 5 added. In the case 23 are several interiors 23a provided whose diameter is repeatedly reduced and increased. The impeller 22 is in the interior 23a accommodated. In the interior 23a is the wheel 22 with a given space between itself and the case 23 arranged. In the case 23 is formed a flow path (not shown) through which a working fluid from the upstream side (the right side in FIG 1 ), which is one side in the O-axis direction, arranged impeller 22 to the wheel 22 adjacent to a downstream side (the left side in FIG 1 ), which is the other side in the O-axis direction, circulates.

The motor 3 is inside the case 5 with a space in the O-axis direction between itself and the compressor 2 accommodated. The motor 3 has a rotor 31 and a stator 32 on. The rotor 31 is with the wave 21 connected. The stator 32 is on an outer peripheral side of the rotor 31 arranged.

The rotor 31 is with the wave 21 integrated and rotatable about the O-axis. The rotor 31 is directly with an outer peripheral side of the shaft 21 connected, which is in a circumferential direction with respect to the O-axis outside, so that they are connected to the shaft 21 of the compressor 2 rotates integrally without the interposition of gears and the like. The rotor 31 has, for example, a rotor core (not shown) in which an induced current flows when the stator 32 generates a rotating magnetic field.

Between the stator 32 and the rotor 31 is a gap 33 provided in the circumferential direction, which is the rotor 31 covering from the outer peripheral side. The stator 32 has a plurality of stator cores (not shown), for example, in the circumferential direction of the rotor 31 and a stator winding (not shown) wound on the stator core. When a current flows from the outside, the stator generates 32 a rotating magnetic field and rotates the rotor 31 , The stator 32 is in the case 5 attached.

The warehouse 4 is inside the case 5 accommodates and supports the wave 21 rotatable. The warehouse 4 This embodiment has several plain bearings 41 and thrust bearings 42 on.

The plain bearing 41 supports a load on the shaft 21 in a radial direction with respect to the O axis. The plain bearings 41 are at both ends of the shaft 21 arranged in the O-axis direction to the motor 3 and the compressor 2 in the O-axis direction. The plain bearing 41 is also arranged between an area where the compressor 2 is provided, and an area in which the engine 3 is provided, which relative to a sealing member described below 51 on the side of the engine 3 is.

The thrust bearing 42 supports a load on the shaft 21 in the O-axis direction by one on the shaft 21 trained pressure ring 21a , The thrust bearing 42 is between the area where the compressor is 2 is provided, and the area in which the engine 3 is provided and located on the side of the compressor 2 relative to the sealing member described below 51 ,

The housing 5 takes the compressor 2 and the engine 3 in it. The housing 5 has a cylindrical shape along the O axis. An inner surface of the housing 5 stands in the direction of the wave 21 between the compressor 2 and the engine 3 in the O-axis direction. The housing 5 is provided at a portion of which the sealing member 51 protrudes, which is a gap between the area where the compressor 2 is provided, and the area in which the engine 3 is provided, seals.

In the heat exchange flow path 600 For example, when a fluid is circulated therein, heat may be transferred between the fluid and the housing 23 be replaced. Through the heat exchange flow path 600 In this embodiment, a fluid flows inside the stator 32 and the rotor 31 and the stator 32 are cooled. Through the heat exchange flow path 600 the fluid flows, whose Temperature has increased when the rotor 31 and the stator 32 are cooled, inside the housing 23 , Through the heat exchange flow path 600 will the fluid inside the housing 23 has flowed, supplied and is from a heat exchanger 601 cooled and flows back inside the stator 32 , The heat exchange flow path 600 This embodiment is a closed loop flow path through which the fluid between the engine 3 and the compressor 2 is circulated.

Note that as the fluid in this embodiment, for example, a cooling medium using a gas such as air and helium is preferably used. When a gas such as air and helium is used as compared with a gas containing a large amount of liquid content such as liquid and water vapor, it is possible to prevent a strength of the heat exchange flow path 600 forming metal material, due to oxidation decreases.

The heat exchange flow path 600 The first embodiment includes the heat exchanger 601 , an introduction flow path 602 , an internal stator flow path 603 , a first connection flow path 604 , a first housing flow path 605 and a first outlet flow path 606 , The heat exchanger 601 this cools the inside of the case 23 streamed fluid. Through the introduction flow path 602 this is done by the heat exchanger 601 cooled fluid in the stator 32 introduced. The internal stator flow path 603 is with the introduction flow path 602 connected and circulates the fluid within the stator 32 , The first connection flow path 604 is with the internal stator flow path 603 connected and leads the fluid to the housing 23 to. The first housing flow path 605 is with the first connection flow path 604 connected and circulates the fluid within the housing 23 , The first outlet flow path 606 is with the first housing flow path 605 connected and discharges the fluid from the inside of the housing 23 and guides the fluid to the heat exchanger 601 to.

The heat exchanger 601 cools the fluid inside the stator 32 and inside the case 23 is circulated. The heat exchanger 601 this embodiment is outside of the housing 5 arranged. When the heat exchanger 601 Heat is exchanged between a surrounding secondary cooling medium and the fluid, the fluid is cooled to a temperature necessary for cooling the engine 3 suitable is.

If the compressor system 10 is used for the underwater production system and provided in the seabed, the surrounding seawater is preferably used as a secondary cooling medium. If the surrounding seawater is used, there is no need for an additional secondary cooling medium for the heat exchanger 601 provided. That is, it is possible to cool the fluid to a temperature at which it is possible to drive the engine 3 by simply exchanging heat with low-temperature seawater in the seabed to cool sufficiently.

If the compressor system 10 is used for FPSO and is provided in a marine facility such as a ship, preferably the ambient air or fresh water stored in the marine facility is used as a secondary cooling medium. When the ambient air or fresh water is used, there is no need for an additional secondary cooling medium for the heat exchanger 601 provided. In addition, it is possible to cool the fluid to a temperature at which it is possible to use the engine 3 sufficiently cool while suppressing the occurrence of events such as corrosion of a pipe.

Through the introduction flow path 602 the fluid gets into the stator 32 from the heat exchanger 601 introduced on the upstream side in the O-axis direction. The introduction flow path 602 is a tube that connects to the interior of the stator 32 from the heat exchanger 601 on an upstream side in the O-axis direction of the stator 32 connected is. A pump 601 , which is configured to supply a fluid, becomes along the introduction flow path 602 intended.

The internal stator flow path 603 is inside the stator 32 arranged so that the fluid within the stator 32 flows. The internal stator flow path 603 this embodiment is with the introduction flow path 602 Connects and circulates the fluid from the upstream to the downstream side in the O-axis direction. The stator flow path 603 is a tube extending in the O-axis direction at a portion near the rotor 31 in the radial direction within the stator 32 extends. The internal stator flow path 603 extends inside the stator 32 from a position on the upstream side in the O-axis direction relative to the rotor 31 to a position on the downstream side in the O-axis direction relative to the rotor 31 , One end of the internal stator flow path 603 on the upstream side in the O-axis direction is with the introduction flow path 602 connected.

Through the first connection flow path 604 becomes the fluid entering the internal stator flow path 603 flowed and whose temperature has risen, from the inside of the stator 32 to the outside of the housing 5 circulates and is supplied to the interior of the housing. The first connection flow path 604 This embodiment is a tube extending from the downstream side in the O-axis direction of the stator 32 to the outside of the housing 5 extends and with the upstream side in the O-axis direction of the housing 23 connected is. The first connection flow path 604 is at one end of the internal stator flow path 603 connected on the downstream side in the O-axis direction.

The first housing flow path 605 is inside the case 23 arranged so that the fluid within the housing 23 flows. The first housing flow path 605 this embodiment is with the first connection flow path 604 Connects and circulates the fluid from the upstream side to the downstream side in the O-axis direction. The first housing flow path 605 is a tube extending in the O-axis direction in the radial direction relative to the inner space 23a in which the impeller 22 inside the case 23 is arranged, extends outwards. One end of the first housing flowpath 605 on the upstream side in the O-axis direction is connected to the first communication flow path 604 connected.

Through the first outlet flow path 606 this will be in the first housing flow path 605 flowed fluid from the inside of the housing 23 to the outside of the housing 5 drained and the heat exchanger 601 fed. The first outlet flow path 606 is a pipe that works with the heat exchanger 601 from the inside of the case 23 on the downstream side in the O-axis direction of the housing 23 connected is. The first outlet flow path 606 is at one end of the first housing flowpath 605 connected on the downstream side in the O-axis direction.

When a temperature difference between the housing 23 and the impeller 22 meets a requirement of a predetermined reference, sets the flow rate adjustment unit 7 the flow rate of the fluid in the heat exchange flow path 600 flows. If in the flow rate adjustment unit 7 This embodiment, the temperature difference between the housing 23 and the impeller 22 is less than a predetermined reference, the flow rate of the first connection flow path 604 flowing fluid decreases. In the flow rate adjustment unit 7 be the temperatures of the case 23 and the impeller 22 not directly measured, it becomes the temperature of the first outlet flow path 606 measured flow of fluid, and the temperature difference between the housing 23 and the impeller 22 is determined.

The flow rate adjustment unit 7 This embodiment has a temperature measuring unit 71 , a valve 72 and a control unit 73 on. The temperature measuring unit 71 measures the temperature of the fluid in the first outlet flow path 606 flows. The valve 72 is in the first connection flow path 604 intended. The control unit 73 sends a signal to the valve 72 to the degree of opening based on the measurement result of the temperature measuring unit 71 adjust.

The temperature measuring unit 71 is in the first outlet flow path 606 intended. The temperature measuring unit 71 is a thermometer designed to measure the temperature of a fluid in the first outlet flow path 606 flows. The temperature measuring unit 71 sends the measured fluid temperature information as a measurement result to the control unit 73 ,

The valve 72 Switches a flowing state of the fluid in the first connection flow path 604 flows. The valve 72 This embodiment is a solenoid valve that is closed to the first communication flow path 604 to restrict, if a signal from the control unit 73 Will be received.

If the measurement result of the temperature measuring unit 71 meets a request for a predetermined reference, sends the control unit 73 a signal to the valve 72 close.

In this embodiment, for example, it is a temperature difference, taking into account that there is no possibility that the housing 23 and the impeller 22 get in touch. In particular, the temperature difference at which it can be determined that there is no possibility that the housing 23 and the impeller 22 come into contact with each other, a temperature difference between the housing 23 and the impeller 22 if the case 23 and the impeller 22 are sufficiently heated, such. When an operation is performed normally.

The control unit 73 This embodiment has an input unit 731 , an investigative unit 732 and an output unit 733 on. The determination unit 732 determines whether the obtained measurement result is a request for a predetermined reference on the basis of the input unit 731 entered result. The output unit 733 sends a signal to the valve 72 according to the determination result of the determination unit 732 , The output unit 733 sends a signal to the valve 72 according to the determination result of the determination unit 732 ,

According to the compressor system described above 10 becomes a current to the stator 32 supplied by an external device such as a generator (not shown). A rotating magnetic field is generated based on the supplied current, and the rotor 31 of the motor 3 starts, along with the wave 21 to rotate. When the wave 21 rotated at high speed, compresses the impeller 22 That along with the wave 21 rotates, a working fluid from the upstream side in the O-axis direction in the compressor 2 flows and discharges the compressed fluid from the downstream side in the O-axis direction.

In the engine 3 this is done by the heat exchanger 601 cooled fluid through the introduction flow path 602 in the stator 32 introduced and flows into the internal stator flow path 603 , Therefore, a section becomes near the rotor 31 of the stator 32 cooled. Therefore, the rotor can 31 and the stator 32 that are heated due to heat being between the rotor 31 and the stator 32 is generated, cooled.

The fluid whose temperature has increased when the rotor 31 and the stator 32 Once cooled, it is once outside the case 5 from the internal stator flow path 603 through the first connection flow path 604 discharged. Then, the fluid whose temperature has risen becomes the first housing flow path 605 fed. When the fluid whose temperature rises in the first housing flow path 605 flows, heat is between the fluid and the housing 23 replaced. As a result, the case becomes 23 heated. That is, heat dissipation by cooling the rotor 31 and the stator 32 is generated, is used to the housing 23 to heat efficiently and quickly. As a result, it is in accordance with a temperature change in the impeller 22 if the compressor system 10 is activated or stopped, possible the housing 23 to warm up quickly. Therefore, it is possible to make a difference between the amount of thermal expansion of the impeller 22 and the amount of thermal expansion of the housing 23 to reduce. Therefore, it is possible to prevent an interval between the impeller and the housing from becoming excessively narrowed while the compressor system is activated or stopped.

The fluid entering the first housing 605 has flowed through the heat exchanger 601 through the first outlet flow path 606 supplied and cooled by this. Then, the fluid becomes the internal stator flow path again 603 from the introduction flow path 602 fed. Since the heat exchange flow path 600 formed in this way as a closed loop flow path, there is no need to supply new fluid. Therefore, it is possible to control the flow rate of the heat exchange flow path 600 to reduce flowing fluid.

The fluid passes through the heat exchanger 601 cooled to efficiently cool the fluid to a temperature at which it is possible, the rotor 31 and the stator 32 to cool sufficiently. That is, a fluid whose temperature has risen too high to the rotor 31 and the stator 32 by cooling in the internal stator flow path 603 and the first housing flow path 605 Therefore, can by heat exchange with the secondary cooling medium through the heat exchanger 601 be cooled. Therefore, it is possible to efficiently reduce the temperature of the fluid.

The fluid passing through the heat exchanger 601 is sufficiently cooled, flows into the internal stator flow path 603 ,

Therefore, a fluid that is the rotor 31 and the stator 32 in the O-axis direction with high accuracy, inside the stator 32 stream. If the rotor 31 rotates, the rotor can 31 and the stator 32 due to heat between the rotor 31 and the stator 32 be heated, efficiently cooled by the O-axis direction. Therefore, it is possible to have a locally high temperature range in the rotor 31 and the stator 32 to suppress. As a result, it is possible to reduce the efficiency of the engine 3 to suppress and increase its life.

The temperature measuring unit 71 measures the temperature of the first outlet flow path 606 flowing fluid and sends the measurement result to the input unit 731 the control unit 73 , In the control unit 73 will be that of the input unit 731 input the entered measurement result and is sent to the determination unit 732 Posted. The determination unit 732 determines whether the measured temperature meets a requirement of a predetermined reference. Therefore, the determination unit determines 732 whether a temperature difference between the housing 23 and the impeller 22 has a value at which it can be assumed that there is no danger of the housing 23 and the impeller 22 get in touch. If the determination unit 732 determines that a request for a reference is satisfied, a signal from the output unit 733 to the valve 72 Posted. This will turn the valve 72 closed to a flow rate of the in the first connection flow path 604 restricting flowing fluid.

Therefore, the determination unit 732 determine if the case 23 and the impeller 22 are sufficiently heated and a temperature difference is reduced, as well as a normal operation is carried out. That is, it is possible to determine if the housing 23 is sufficiently heated and a difference between an amount of thermal expansion of the impeller 22 and the amount of thermal expansion of the housing 23 is reduced.

If the determination unit 732 determines that a request for a reference is satisfied causes the control unit 73 that the valve 72 is closed. Therefore, it is possible to have only a necessary amount of the fluid in the heat exchange flow path 600 to circulate. If, for example, the temperature difference between the housing 23 and the impeller 22 is sufficiently small and there is no need for the housing 23 To heat, it is possible to prevent the fluid continuously in the heat exchange flow path 600 is circulated. Therefore, it is possible for the fluid in the heat exchange flow path 600 to circulate efficiently.

Second embodiment

Next is a compressor system 12 according to a second embodiment with reference to 2 described.

In the second embodiment, the same components as in the first embodiment will be denoted by the same reference numerals, and details thereof will not be described. In the compressor system 12 In the second embodiment, the configuration of a heat exchange flow path differs 620 from that of the first embodiment.

In the heat exchange flow path 620 of the compressor system 12 In the second embodiment, a compressed fluid, which is a working fluid passing through the impeller 22 is compressed, used as a fluid, and the fluid is in the gap 33 between the stator 32 and the rotor 31 (hereinafter referred to simply as the "gap 33 "Designated) circulated. More specifically, as in 2 is shown, the heat exchange flow path 620 In the second embodiment, a middle stage extraction fluid introduction flow path 622 , a second connection flow path 624 , a second housing flow path 625 and a second outlet flow path 626 on. Through the middle stage extraction fluid introduction flow path 622 the compressed fluid is discharged from a middle stage of the compressor 2 pulled out and into the gap 33 of the motor 3 introduced. Through the second connection flow path 624 will that be in the gap 33 flowed pressure fluid to the housing 23 fed. The second housing flow path 625 is with the second connection flow path 624 connected and the compressed fluid flows within the housing 23 , The second outlet flow path 626 is with the second housing flow path 625 connected and the compressed fluid is from the inside of the housing 23 to the outside of the housing 5 issued.

Note that the gap 33 in this embodiment, there is a space between the stator 32 and the rotor 31 is trained. The gap 33 is a space that is between surfaces that face each other in the radial direction, between an outer peripheral surface, in the radial direction of the rotor 31 facing outward, and an inner peripheral surface, in the radial direction of the stator 32 facing inward, is arranged.

Through the middle stage extraction fluid introduction flow path 622 that gets through the impeller 22 compressed fluid from the middle stage of the compressor 2 pulled out and the upstream side in the O-axis direction of the gap 33 fed. The extraction fluid introduction flow path 622 This embodiment is a pipe coming from the middle stage of the compressor 2 to the upstream side in the O-axis direction of the engine 3 inside the case 5 connected is. The intermediate stage extraction fluid introduction flow path 622 is with the upstream side in the O-axis direction relative to the rotor 31 and the stator 32 inside the case 5 connected. That is, through the middle stage extraction fluid introduction flow path 622 the compressed fluid becomes the gap 33 supplied from the upstream side in the O-axis direction. In the middle stage extraction fluid introduction flow path 622 is the valve 72 provided on a section that is outside of the housing 5 is arranged.

Through the second connection flow path 624 is the compressed fluid that is in the gap 33 from the upstream side to the downstream side in the O-axis direction, out of the gap 33 pulled out and the second Gehäusestömungspfad 625 fed. The connection flow path 624 is a pipe that comes from the housing 23 with the downstream side in the O-axis direction of the engine 3 inside the case 5 connected is. The second connection flow path 624 is with the downstream side in the O-axis direction relative to the rotor 31 and the stator 32 inside the case 5 connected. That is, through the second connection flow path 624 the compressed fluid is out of the gap 33 pulled out on the downstream side in the O-axis direction.

The second housing flow path 625 is inside the case 23 arranged so that the fluid within the housing 23 flows. The second housing power path 625 is with the second connection flow path 624 connected, so that compressed fluid flows downstream from the upstream side in the O-axis direction through the second housing flow path. The second housing flow path 625 is a tube extending in the O-axis direction in the radial direction relative to the inner space 23a in which the impeller 22 inside the case 23 is arranged, extends outwards. One end of the second housing flowpath 625 on the upstream side in the O-axis direction is connected to the second communication flow path 624 connected.

The second outlet flow path 626 is with the second housing flow path 625 connected so that the compressed fluid inside the housing 23 flows from the downstream side in the O-axis direction to the outside of the housing 5 is omitted. The second outlet flow path 626 is a tube that connects to the outside of the case 5 from the inside of the case 23 on the downstream side in the O-axis direction of the housing 23 connected is. The second outlet flow path 626 is at one end of the second housing flowpath 625 connected on the downstream side in the O-axis direction. In the second outlet flow path 626 is the temperature measuring unit 71 provided on a section that is outside of the housing 5 is arranged.

According to the compressor system described above 12 is the compressed fluid, which is a working fluid passing through the impeller 22 is compressed from the middle stage of the compressor 2 through the middle stage extraction fluid introduction flow path 622 pulled out. Then, the compressed fluid becomes the upstream side in the O-axis direction of the gap 33 fed. Therefore, the compressed fluid flows in the gap 33 from the upstream side to the downstream side in the O-axis direction and the vicinity of the gap 33 is cooled in the O-axis direction. Therefore, the rotor can 31 and the stator 32 which is heated due to heat generated when the rotor 31 rotated, cooled.

That in the gap 33 flowing compressed fluid is from the downstream side in the O-axis direction of the gap 33 through the second connection flow path 624 pulled out and the second Gehäusestömungspfad 625 fed. Therefore, it is possible the case 23 due to the compressed fluid, whose temperature has increased when the rotor 31 and the stator 32 be cooled. That is, heat dissipation by cooling the rotor 31 and the stator 32 is generated, is used to the housing 23 to heat efficiently and quickly. As a result, it is in accordance with a temperature change in the impeller 22 if the compressor system 10 enabled or stopped, possible, the housing 23 to warm up quickly. Therefore, it is possible to make a difference between the amount of thermal expansion of the impeller 22 and the amount of thermal expansion of the housing 23 to reduce. Therefore, it is possible to prevent a space between the impeller and the housing from becoming excessively narrowed while the compressor system is activated or stopped.

Part of the working fluid passing through the compressor 2 is compressed and is extracted as that in the heat exchange flow path 620 flowing fluid used. Therefore, the fluid in the heat exchange flow path 620 flow without using a device configured to send a fluid, such as the pump 601 , The rotor 31 and the stator 32 are cooled by the working fluid whose temperature has increased when passing through the impeller 22 is compressed. Therefore, the working fluid can be further heated and the housing 23 be supplied. Therefore, it is possible to effectively heat the case with a simple configuration.

Third embodiment

Next is a compressor system 13 according to a third embodiment with reference to 3 described.

In the third embodiment, the same components as in the first and second embodiments are denoted by the same reference numerals, and details thereof will not be described. In the compressor system 13 In the third embodiment, the configuration of a heat exchange flow path differs 630 of the first and second embodiments.

In the heat exchange flow path 630 of the compressor system 13 In the third embodiment, in contrast to the second embodiment, a compressed fluid is used as the fluid, and the fluid does not become the side of the engine 3 fed. More specifically, as in 3 is shown, contains the heat exchange flow path 630 the third embodiment, a second intermediate stage extraction fluid introduction flow path 632 , By the second intermediate stage extraction fluid introduction flow path 632 The compressed fluid that has been compressed is removed from the middle stage of the compressor 2 is extracted and becomes the second housing flow path 625 fed. Similar to the second embodiment, the heat exchange flow path 630 the third embodiment, the second Gehäusestömungspfad 625 and the second outlet flow path 626 on.

By the second intermediate stage extraction fluid introduction flow path 632 is the compressed fluid passing through the impeller 22 is compressed from the middle stage of the compressor 2 pulled out and the second Gehäusestömungspfad 625 fed. The second intermediate stage extraction fluid introduction flow path 632 This embodiment is a tube that from the middle stage of the compressor 2 to the upstream side in the O-axis direction of the second housing flow path 625 connected is. In the second intermediate stage extraction fluid introduction flowpath 632 becomes the valve 72 provided on a section that is outside of the housing 5 is arranged. In the middle stage extraction fluid introduction flow path 632 is the valve 72 provided on a section that is outside of the housing 5 is arranged.

According to the compressor system described above 13 becomes a part of the working fluid passing through the compressor 2 is compressed and extracted as that in the heat exchange flow path 620 flowing fluid used. Therefore, the fluid in the heat exchange flow path 620 flow without using a device configured to send a fluid, such as the pump 601 , The working fluid whose temperature has increased when passing through the impeller 22 can be compressed, the housing 23 be supplied. Therefore, it is possible to effectively heat the case with a simple configuration.

Fourth embodiment

Next is a compressor system 14 according to a fourth embodiment with reference to 4 described.

In the fourth embodiment, the same components as in the first to third embodiments will be denoted by the same reference numerals, and details thereof will not be described. In the compressor system 14 In the fourth embodiment, the configuration of a heat exchange flow path differs 640 from the first to the third embodiment.

When the compressed fluid than that in the heat exchange flow path 640 flowing fluid is used, the present invention is not limited to the compressed fluid coming out of the middle stage of the compressor 2 as in the second embodiment and the third embodiment is pulled out, and that by the impeller 22 compressed working fluid can be extracted. Therefore, for example, the compressed fluid from the last stage of the compressor 2 be extracted.

In the heat exchange flow path 640 of the compressor system 14 In the fourth embodiment, the compressed fluid from the last stage of the compressor 2 extracted. More specifically, as in 4 is shown, contains the heat exchange flow path 640 In the fourth embodiment, a late stage extraction fluid introduction flow path 642 through which the compressed fluid from the last stage of the compressor 2 extracted and the second Gehäusestömungspfad 625 is supplied.

By the late stage extraction fluid introduction flow path 642 This is the compressed fluid while passing through the impeller 12 maximum is compressed from the last stage of the compressor 2 pulled out and the second Gehäusestömungspfad 625 fed. The late stage extraction fluid introduction flow path 642 This embodiment is a tube from the last stage of the compressor 2 to the upstream side in the O-axis direction of the second housing flow path 625 connected is. The late stage extraction fluid introduction flow path 642 through which the compressed fluid to the outside of the housing 23 is discharged with one in the last stage of the compressor 2 provided outlet opening (not shown). In the late stage extraction fluid introduction flow path 642 is the valve 72 provided on a section that is outside of the housing 5 is arranged.

According to the compressor system described above 14 can the case 23 are heated by the compressed fluid having a higher temperature than that of the third embodiment.

The embodiments of the present invention have been described in detail with reference to the drawings, but configurations and combinations thereof in the embodiments are only examples, and additions, omissions, substitutions, and other modifications of the configurations may be made without departing from the scope of the present invention. In addition, the present invention is not limited to the embodiments and is limited only by the scope of the appended claims.

It should be noted that the present invention does not apply to the heat exchanger 601 that's outside the case 5 as arranged in the first embodiment, and a heat exchanger capable of cooling a fluid may be provided at any position. For example, the heat exchanger 601 inside the case 5 be arranged. The number of heat exchangers 601 is not limited to one as in this embodiment, but it can also be more heat exchangers 601 be provided.

A method for determining a temperature difference between the housing 23 and the impeller is not limited to the method wherein the temperatures of the fluids flowing in the first housing flowpath 605 and the second housing flow path 625 are circulated as measured in this embodiment. A temperature difference between the housing 23 and the impeller can by directly measuring the temperatures of the housing 23 and the impeller 22 be determined. A temperature difference between the housing 23 and the impeller can according to the speed of the shaft 21 be determined if a relationship between the temperature difference between the housing 23 and the impeller 22 and the speed of the shaft 21 determined in advance.

The first housing flow path 605 and the second housing flow path 625 through which the fluid passes to the housing 23 are not limited to paths having a structure extending in the O-axis direction within the housing 23 as in this embodiment. The first housing flow path 605 and the second housing flow path 625 may have a configuration in the heat between the circulating fluid and the housing 23 can be exchanged. For example, the first housing flow path 605 and the second housing flow path 625 between the case 23 and the housing 5 be provided. In this case, the first housing flow path 605 and the second housing flow path 625 spirally on an outer circumference of the housing 23 or may be arranged so as to extend in the O-axis direction in a linear shape.

Industrial Applicability

According to the above compressor system, it is possible to heat the housing using the fluid whose temperature has increased when the rotor and the stator are cooled. Thereby, it can be prevented that an interval between the impeller and the housing is excessively narrowed.

LIST OF REFERENCE NUMBERS

10, 12, 13, 14

compressor system

O

axis

2

compressor

21

wave

21a

pressure ring

22

Wheel

23

casing

23a

inner space

3

engine

31

rotor

32

stator

33

gap

4

camp

41

bearings

42

thrust

5

casing

51

sealing member

600, 620, 630, 640

Heat exchange flow path

601

heat exchangers

601

pump

602

Introduction flow path

603

internal stator flow path

604

first connection flow path

605

first housing flow path

606

first outlet flow path

7

Flow rate setting unit

71

Temperature measurement unit

72

Valve

73

control unit

731

input unit

732

determining unit

733

output unit

622

Intermediate extraction fluid introduction flow path

624

second connection flow path

625

second housing flow path

626

second outlet flow path

632

second intermediate stage extraction fluid introduction flow path

642

Late-stage extraction fluid introduction flow path

Claims (3)

A compressor system comprising: a motor having a rotor configured to rotate about an axis and having a stator disposed on an outer peripheral side of the rotor; a compressor having an impeller configured to compress a working fluid by co-rotating with the rotor, and a compressor A housing covering the impeller from an outer peripheral side; and a heat exchange flow path through which a fluid inside the stator or in a gap between the stator and the rotor is flowed and heat is exchangeable between the fluid and the housing. A compressor system according to claim 1, wherein the fluid is a working fluid which is compressed by the impeller. A compressor system according to claim 1 or 2, comprising a flow rate adjustment unit configured to adjust a flow rate of the fluid flowing in the heat exchange flowpath when a temperature difference between the housing and the impeller meets a requirement of a predetermined reference.

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