JP2011188642A - Rotating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rotating device that suppresses vibration of a rotor shaft exceeding the absorption capacity of a damper in use. <P>SOLUTION: The rotating device 100 is configured as follows. Each bearing unit 24 supports a connection shaft 21 rotated integrally with a rotor shaft 131. The bearing unit has high rigidity because it is applied with a pre-load. Each bearing unit 24 is directly held to a shaft housing 22 firmly fixed by being connected to a storage body 11 for storing a stator 14. Accordingly, even when a vibration (resonance) occurs in a rotor 13 due to high-speed rotation of the rotor 13, for example, at tens of thousands of rpms on the side of a dynamo part 1 and a damper 16 cannot completely absorb the vibration, vibration of the connection shaft 21 is reduced to the minimum on the side of an adaptor part 2, thereby making the rotation center of the connection shaft 21 substantially constant. Namely, it is possible to suppress the vibration of the rotor shaft 131 of a dynamo-electric machine 100 exceeding the absorption capacity of the damper 16 in use. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a rotating device such as a dynamo and a motor.

  A squeeze film damper is frequently used in a dynamo or motor bearing portion that rotates at high speed in order to attenuate shaft vibration generated by the high-speed rotation.

  In the example shown in FIG. 5 of Patent Document 1, the vibration of the generator shaft rotating at high speed is reduced by providing the squeeze film damper on the outer peripheral side of the radial bearing that supports the rotor (for example, the specification of Patent Document 1). Paragraph [0028]). Further, in Patent Document 1, as shown in FIGS. 2 and 3, a large number of holes through which a lubricant passes are formed, and a plurality of thin plates formed in a C shape when viewed in the thrust direction are stacked. A damper is also disclosed (paragraph [0022] in the specification of Patent Document 1).

  Further, in the gas turbine described in Patent Document 2, a technique for positioning the bearing holder when a bearing holder that holds the bearing is attached to the housing of the gas turbine is disclosed. A squeeze film damper is formed on the outer peripheral side of the bearing housing portion of the bearing holder. The bearing holder has a cylindrical portion formed integrally with the bearing housing portion, and one end (inlay portion) of the cylindrical portion is fitted into the hole portion of the housing. With such a configuration, the bearing housing portion is positioned with high concentricity with respect to the hole portion of the housing (see, for example, paragraph [0015] and FIGS. 1 and 2 of Patent Document 2).

Japanese Patent Application Laid-Open No. 2004-336917 Japanese Patent No. 2949913

  In the rotating device provided with the squeeze film damper and other dampers described in Patent Documents 1 and 2, the vibration can be attenuated to some extent, but cannot sufficiently absorb the vibration, and the rotation center of the rotor shaft Is not constant. For example, when the rotating device is used as a dynamo, if vibration occurs in the dynamo, the rotor on the drive source side connected to the dynamo may vibrate and be damaged. Therefore, it is necessary to suppress vibration that cannot be absorbed by the damper alone.

  In view of the circumstances as described above, an object of the present invention is to provide a rotating device that can suppress vibrations of a rotor shaft that cannot be absorbed even if a damper is used.

In order to achieve the above object, a rotating device according to an aspect of the present invention includes a rotor, a stator, a first bearing, a damper, a container, a connecting shaft, a second bearing, and a holding body. It comprises.
The rotor has a rotor shaft.
The stator is disposed around the rotor.
The first bearing rotatably supports the rotor shaft.
The damper elastically supports the first bearing.
The housing body houses the stator and holds the first bearing via the damper.
The connection shaft is connected to an end of the rotor shaft.
The second bearing rotatably supports the connection shaft and is preloaded.
The holding body is connected to the container and holds the second bearing.

  When the rotating device is used as a motor, the connecting shaft serves as an output shaft that outputs the power of the motor to an external device. On the other hand, when the rotating device is used as a dynamo, the connecting shaft is an input shaft to which power from an external device is input.

  In the present invention, the housing that houses the stator holds the first bearing that supports the rotor via the damper. The second bearing that supports the connecting shaft that rotates integrally with the rotor has high rigidity because it is preloaded, and the second bearing is connected to a housing that houses the stator. Is held by the body. Therefore, even if the damper may not be able to absorb the vibration of the rotating rotor, the vibration of the connecting shaft is suppressed as much as possible, and the rotation center of the connecting shaft that functions as the input or output shaft can be made substantially constant. it can. That is, it is possible to suppress vibration of the rotor shaft of the rotating device that cannot be absorbed even if the damper is used. Thereby, for example, damage to an external device connected to the connecting shaft can be prevented.

  A fixed position preload may be applied to the second bearing. With the fixed position preload, for example, the rigidity of the second bearing can be increased and the number of components of the bearing can be reduced as compared with the case where the constant pressure preload is applied to the second bearing. In particular, in the present invention, the rotor, the stator, the first bearing, the damper, and the housing are added with the components such as the connecting shaft, the second bearing, and the holding body. It is necessary to reduce the total number of parts as much as possible and satisfy the condition of high rigidity. That is, the merit of using the second bearing applied with the constant position preload is greater than that applied with the constant pressure preload.

  As described above, according to the present invention, it is possible to suppress the vibration of the rotor shaft of the rotating device, which cannot be absorbed even by using the damper.

FIG. 1 is a cross-sectional view showing a dynamo as a rotating device according to an embodiment of the present invention. FIG. 2 is an enlarged cross-sectional view showing the bearing unit of the adapter unit.

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

  FIG. 1 is a cross-sectional view showing a dynamo as a rotating device according to an embodiment of the present invention. In the following description, for convenience of description, the right side of the dynamo 100 in FIG.

  The dynamo 100 includes a dynamo unit 1 and an adapter unit 2 connected to the front side of the dynamo unit 1. The dynamo unit 1 includes a housing 11, and the housing 11 includes a cylindrical housing 111 having both ends opened in the thrust direction (axial direction), and covers 112 attached to both ends of the housing 111. Have.

  A rotor 13 is disposed at the center of the housing 111, and a stator 14 having a core 141 and a coil 142 is disposed around the rotor 13. The stator 14 is fixed to the inner wall of the housing 111. The rotor 13 has a rotor shaft 131, and a permanent magnet 132 is fixed around the rotor shaft 131. The rotor shaft 131 is rotatably supported by the bearing 15 near both ends of the rotor shaft 131.

  Cylindrical bearing mounting portions 112a are provided in the center of both covers 112, and both end portions of the rotor shaft 131 are disposed in the bearing mounting portions 112a. Between the inner peripheral surface of the bearing mounting portion 112a and the bearing 15, there are provided dampers 16 that elastically support the bearing 15 respectively.

  The bearing 15 may be anything such as a radial bearing or an angular bearing.

  As the damper 16, which is schematically shown in FIG. 1, a squeeze-flum damper (SFD) is typically used. Specifically, a seal member such as an O-ring is attached to an outer ring (not shown) of the bearing 15, and SFD is formed by oil filled between the seal member and the inner peripheral surface of the bearing mounting portion 112a. Instead of SFD, a mechanical damper that does not use an oil film may be used.

  The adapter unit 2 includes a connection shaft 21 connected to the front end portion of the rotor shaft 131 and a bearing unit 24 that rotatably supports the connection shaft 21. The connection shaft 21 is connected to the rotor shaft 131 by, for example, a spline coupling structure 1321 and has high rigidity with respect to the rotation direction of the shafts 131 and 21. The bearing units 24 are provided at two appropriate positions on the connecting shaft 21. The two bearing units 24 have substantially the same configuration.

  The adapter unit 2 includes a shaft housing 22 that is connected to the housing 11 of the dynamo unit 1 and serves as a holding body that holds the bearing units 24. A cover member 23 having a hole 23a is attached to the front side of the shaft housing 22, and an end 21a on the front side of the connection shaft 21 projects outside through the hole 23a. As shown in FIG. 1, the shaft housing 22 may be connected to the cover 112 of the container 11 or may be connected to the housing 111. Although not shown in FIG. 1, when the container 11 and the shaft housing 22 are connected by, for example, flange connection, the rigidity of both can be improved.

  The shaft housing 22 has a holding portion 225 having a cylindrical space 223 therein. The bearing unit 24 is held so as to be fitted to the inner peripheral surface of the holding portion 225.

  FIG. 2 is an enlarged cross-sectional view showing one bearing unit 24 of the two bearing units 24 of the adapter unit 2. The bearing unit 24 includes two bearings 241 and 242 and a spacer 243 provided therebetween. As the two bearings 241 and 242, for example, angular bearings to which a fixed position preload is applied are used, and thereby a combined angular bearing is configured. In other words, in this combined angular bearing, for example, the balls 2415 and 2425 included in the angular bearings 241 and 242 respectively have a predetermined contact angle, and are symmetrical in two oblique directions with respect to a plane perpendicular to the thrust direction. The connecting shaft 21 is supported.

  The operation of the dynamo 100 configured as described above will be described.

  A driving shaft of a power source (not shown) (not shown) is connected to the front end portion 21a of the connecting shaft 21 via a coupling (not shown). When this dynamo 100 is used as a test apparatus (dynamometer) for testing the operation of the power source, a torque meter or the like is connected between the connection shaft 21 and the drive shaft of the power source. In some cases.

  When a drive shaft of a power source (not shown) rotates, the connecting shaft 21 and the rotor 13 connected to the connecting shaft 21 rotate integrally. As the rotor 13 rotates, electric power is generated in the coil 142 due to the interaction between the permanent magnet 132 of the rotor 13, the core 141 of the stator 14, and the coil 142. The rotational speeds of the connecting shaft 21 and the rotor 13 are 0 to 50000 rpm, but are not limited to this range.

  In the present embodiment, as described above, the bearing unit 24 that supports the connection shaft 21 that rotates integrally with the rotor shaft 131 is preliminarily applied and thus has high rigidity. The bearing unit 24 is directly held by a shaft housing 22 that is connected and firmly fixed to the housing 11 that houses the stator 14. Therefore, even if the rotor 13 rotates at a high speed of, for example, several tens of thousands rpm on the dynamo unit 1 side and vibration (resonance) occurs in the rotor 13, and the damper 16 may not be able to absorb this vibration, the adapter unit 2 side The vibration of the connecting shaft 21 is suppressed as much as possible, and the center of rotation of the connecting shaft 21 can be made substantially constant. That is, vibration of the rotor shaft 131 of the dynamo 100 that cannot be absorbed even when the damper 16 is used can be suppressed. Thereby, damage to a power source etc. connected to the connecting shaft 21, for example, can be prevented.

  In addition, the use of the bearing unit 24 to which the fixed position preload is applied can increase the rigidity of the bearing unit 24 as compared to the case where the constant pressure preload is used, for example. The number of parts can be reduced. In particular, in the present embodiment, the rotor 13, the stator 14, the bearing 15, the damper 16, and the housing 11 are added with the components such as the connecting shaft 21, the bearing unit 24, and the shaft housing 22, and the entire dynamo 100 has many components. Therefore, it is necessary to reduce the total number of parts of the dynamo 100 as much as possible and satisfy the condition of high rigidity. That is, the merit of using the bearing unit 24 to which the constant position preload is applied is larger than that to which the constant pressure preload is applied.

  The embodiment according to the present invention is not limited to the embodiment described above, and other various embodiments are realized.

  The combination angular bearing as the bearing unit 24 has two angular bearings, but may be a combination of three or more angular bearings.

  In addition, the angular bearing is applied with a fixed position preload, but may be used with a constant pressure preload.

  In the above embodiment, the bearing unit 24 is arranged so as to be in direct contact with the inner peripheral surface of the holding portion 225 of the shaft housing 22. However, a bearing holder (not shown) may be provided on the outer peripheral portion of the bearing unit 24, and the bearing holder may be held so as to be fitted to the inner peripheral surface of the holding portion 225 of the shaft housing 22. In this case, a bearing holder having high rigidity may be used.

  In the above-described embodiment, the rotating device is used as the dynamo 100, but may be used as a motor. In this case, the connecting shaft 21 functions as an output shaft that outputs the driving force of the motor, and the motor as the rotating device gives the rotational power to an external device (not shown) connected to the output shaft.

  Alternatively, the rotating device 100 may be used as a turbine. In this case, the stator does not necessarily have a core and a coil, and may be a housing that accommodates the rotor in which the stator and the housing are integrated.

DESCRIPTION OF SYMBOLS 1 ... Dynamo part 2 ... Adapter part 11 ... Housing 13 ... Rotor 14 ... Stator 15 ... Bearing (equivalent to a 1st bearing)
16 ... Damper 21 ... Connection shaft 22 ... Shaft housing (corresponding to holding body)
24 ... Bearing unit (corresponding to the second bearing)
100 ... Dynamo (equivalent to a rotating device)
131 ... Rotor shaft

Claims (2)

A rotor having a rotor shaft;
A stator disposed around the rotor;
A first bearing rotatably supporting the rotor shaft;
A damper for elastically supporting the first bearing;
A housing for housing the stator and holding the first bearing via the damper;
A connecting shaft connected to an end of the rotor shaft;
A second bearing that rotatably supports the connecting shaft and is preloaded;
A rotating device comprising: a holding body connected to the housing body and holding the second bearing. The rotating device according to claim 1,
The second bearing is subjected to a fixed position preload.

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