JP3785522B2 - Control type magnetic bearing device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a control type magnetic bearing device which is used in, for example, a turbo molecular pump and rotates a non-contact support of a rotating body with a magnetic bearing.
[0002]
[Prior art]
As this type of control-type magnetic bearing device, one having a machine main body and a controller connected to the machine main body via a cable is known.
[0003]
The machine body includes a plurality of displacement sensors for detecting axial and radial displacements of the rotating body, and a plurality of sets that support the rotating body in a non-contact manner in the axial and radial directions by the magnetic attraction force of the electromagnets that make a pair. A magnetic bearing, an electric motor that rotates the rotating body, a protective bearing that restricts the movable range of the rotating body, and the like are provided. The protective bearing regulates the movable range in the axial direction and the radial direction of the rotating body, and mechanically supports the rotating body when the supporting force by the magnetic bearing is lost.
[0004]
The controller uses a predetermined control parameter to control the excitation current supplied to the electromagnet based on the output of the displacement sensor.
[0005]
In such a magnetic bearing device, the form of the machine body differs depending on the application, and when the form of the machine body changes, it is necessary to change the control parameters in the controller. The form of the machine body varies depending on the type of the rotating body (weight, natural frequency, center of gravity, etc.), the type of electromagnet, the positional relationship between the rotating body, the electromagnet, and the displacement sensor. For this reason, conventionally, a plurality of types of machine main bodies having different formats and a plurality of types of controllers having different control parameters are prepared, and these are used in combination depending on the application.
[0006]
However, if this is done, it is necessary to prepare another type of controller in accordance with the type of the machine body, which is uneconomical. In addition, if the combination of the machine body and the controller is wrong, the control parameters may be inappropriate and the control of the position of the rotating body by the magnetic bearing may become unstable. To eliminate such inconvenience, when connecting the machine body and controller, the controller can automatically identify the machine body type and check whether the controller is compatible with the machine body. However, in the conventional magnetic bearing device, the control in the controller is mainly analog PID control and has only a function of outputting an output signal to the electromagnet in response to an input signal from the displacement sensor. It was impossible to identify the body type.
[0007]
[Problems to be solved by the invention]
An object of the present invention is to provide a control type magnetic bearing device that can automatically identify the type of a machine body and change control parameters in accordance with the machine body type.
[0010]
[Means for Solving the Problems and Effects of the Invention]
A control type magnetic bearing device according to the present invention includes a plurality of displacement sensors for detecting a displacement of a rotating body and a plurality of sets of magnets that support the rotating body in a non-contact manner at a predetermined target position by a magnetic attraction force of a pair of electromagnets. In the control type magnetic bearing device, comprising: a machine main body having a bearing; and a controller having an electromagnet control means for controlling an excitation current supplied to the electromagnet based on an output of the displacement sensor using a control parameter. A digital program capable of outputting a digital control signal for controlling the excitation current based on a digital displacement signal representing the displacement of the rotating body obtained from the output of the displacement sensor using the control parameter processing means comprises a nonvolatile memory device, in the nonvolatile storage device, temporary identification A control parameter, wherein the control parameter is stored for a plurality of sets of operation corresponding to each type of machine body, said digital processing means, the identification of identifying the type of the machine body said nonvolatile memory device An identification means for selecting the control parameter corresponding to the result is provided, and the identification means adds the rotating body after supporting the rotating body in a non-contact manner at a predetermined target position using the temporary control parameter for identification. The type of the machine body is identified based on the response status of the rotating body at this time.
[0011]
For example, an MPU (microprocessor), a digital signal processor or the like is used as the digital processing means capable of software programming. A digital signal processor refers to dedicated hardware that inputs a digital signal and outputs a digital signal, can be software-programmed, and can perform high-speed real-time processing. Hereinafter, this is abbreviated as “DSP”.
[0012]
As the nonvolatile storage device, for example, an appropriate device such as a flash memory or an EPROM is used.
[0013]
When the form of the machine body changes, the response state of the rotating body when the rotating body is vibrated changes. Therefore, the form of the machine body can be identified by examining the response state of the rotating body at this time. Therefore, according to this invention, it is possible to automatically identify the format of the machine body by an electromagnet control means of the controller. Then, based on the identification result of the machine main body, one suitable for the machine main body can be automatically selected and used from a plurality of sets of operation control parameters stored in the nonvolatile storage device. For this reason, one type of controller can be used for a plurality of types of machine main bodies, and the number of types of controllers to be prepared is reduced, which is economical .
[0015]
For example, the identification means vibrates the rotating body by adding a predetermined digital identification signal to the digital control signal, and obtains the response status of the rotating body from the digital displacement signal at that time. .
[0016]
In this way, the rotating body can be easily vibrated simply by adding the digital signals.
[0017]
For example, the digital identification signal is a sine wave signal having a constant frequency.
[0018]
For example, the digital identification signal is a variable frequency sine wave signal.
[0019]
When the machine body type changes, the frequency response of the rotating body also changes. Therefore, the type of the rotator can be identified by adding the sine wave signal to the digital control signal to vibrate the rotator and examining the response (frequency response) status at that time. In particular, when a variable frequency sine wave signal is used, the type of the machine body can be accurately identified by examining the frequency response to a plurality of sine wave signals.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
[0021]
FIG. 1 is a longitudinal sectional view showing a main part of a mechanical part of a control type magnetic bearing device, FIG. 2 is a transverse sectional view thereof, and FIG. 3 is a block diagram showing an example of its electrical configuration.
[0022]
The magnetic bearing device includes a machine body (1) and a controller (2) connected by a cable, and a personal computer (3) is connected to the controller (2).
[0023]
The magnetic bearing device is of a vertical type in which a vertical axis rotating body (5) rotates inside a vertical cylindrical casing (4). In the following description, the control axis (axial control axis) in the axial direction (vertical direction) of the rotating body (5) is the Z axis, and two radial (horizontal) control axes that are orthogonal to the Z axis and orthogonal to each other. Let (radial control axis) be the X axis and the Y axis.
[0024]
The machine body (1) has a pair of axial magnetic bearings (6) for supporting the rotating body (5) in a non-contact manner in the axial direction, and two sets of radial magnets for supporting the rotating body (5) in a non-contact manner in the radial direction. Bearing (7) (8), displacement detector (9) for detecting axial and radial displacement of the rotating body (5), built-in type electric motor (10) for rotating the rotating body (5) at high speed ), And when the rotating body (5) cannot be supported by the magnetic bearings (6), (7), (8) by restricting the moving range in the axial direction and the radial direction of the rotating body (5). Two pairs of upper and lower protective bearings (11) and (12) are provided as restricting means for mechanically supporting the rotating body (5) at the position.
[0025]
The controller (2) is provided with a sensor circuit (13), a magnetic bearing drive circuit (14), an inverter (15), a DSP board (16) and a serial communication board (17), and the DSP board (16) A DSP (18), a ROM (31) as digital processing means, a flash memory (19) as a nonvolatile storage device, an AD converter (20), and a DA converter (21) are provided. The controller (2) and the personal computer (3) are installed at a distance from each other, and the flash memory (19) and the personal computer (3) are connected via the communication board (17) and the cable (22).
[0026]
The displacement detector (9) includes an axial displacement sensor (23) for detecting the axial displacement of the rotating body (5), and an upper and lower position for detecting the radial displacement of the rotating body (5). Two sets of radial displacement sensor units (24) and (25) are provided.
[0027]
The axial magnetic bearing (6) is a pair of axial electromagnets (26a) (26b) arranged so as to sandwich a flange portion (5a) formed integrally with the lower portion of the rotating body (5) from both sides in the Z-axis direction. It has. The axial electromagnet is generically designated by reference numeral (26).
[0028]
The axial displacement sensor (23) is arranged to face the lower end surface of the rotating body (5) from the lower side in the Z-axis direction, and is a distance signal proportional to the distance (gap) from the lower end surface of the rotating body (5). Is output.
[0029]
The two sets of radial magnetic bearings (7) and (8) are arranged on the upper side of the axial magnetic bearing (6) at predetermined intervals in the upper and lower directions, and the motor (10) is arranged between them. Yes. The upper radial magnetic bearing (7) includes a pair of radial electromagnets (27a) (27b) arranged so as to sandwich the rotating body (5) from both sides in the X-axis direction, and the rotating body (5) in the Y-axis direction. A pair of radial electromagnets (27c) and (27d) are arranged so as to be sandwiched from both sides in the direction. These radial electromagnets are collectively referred to by reference numeral (27). Similarly, the lower radial electromagnet (8) also includes two pairs of radial electromagnets (28a) (28b) (28c) (28d). These radial electromagnets are also collectively referred to by reference numeral (28).
[0030]
The upper radial displacement sensor unit (24) is arranged in the vicinity of the upper radial magnetic bearing (7), and the rotating body from both sides in the X axis direction in the vicinity of the electromagnets (27a) and (27b) in the X axis direction. A pair of radial displacement sensors (29a) (29b) arranged so as to sandwich (5) and the rotating body (5) from both sides in the Y-axis direction in the vicinity of the electromagnets (27c) (27d) in the Y-axis direction A pair of radial displacement sensors (29c) and (29d) are arranged so as to be sandwiched therebetween. These radial displacement sensors are collectively referred to by reference numeral (29). Similarly, the lower radial displacement sensor unit (25) is arranged in the vicinity of the lower radial magnetic bearing (8), and two pairs of radial displacement sensors (30a) (30b) (30c) (30d) It has. These radial displacement sensors are also collectively referred to by reference numeral (30). Each radial displacement sensor (29) (30) outputs a distance signal proportional to the distance from the outer peripheral surface of the rotating body (5).
[0031]
The electromagnets (26) (27) (28) and the displacement sensors (23) (29) (30) are fixed to the casing (4).
[0032]
The ROM (31) of the controller (2) stores processing programs for the DSP (18). The flash memory (19) has a control parameter table storing the control parameters of the magnetic bearings (6), (7) and (8), and an identification signal table storing identification signal data (vibration data) described later. A bias current value table storing a bias current value, which will be described later, is provided. In the control parameter table, a temporary control parameter for identification and a plurality of sets of operation control parameters respectively corresponding to a plurality of types of the machine body (1) are stored. In the case of this embodiment, the identification signal table stores sine wave signal data having a constant frequency as the excitation data. The contents of these tables can be rewritten using a personal computer (3).
[0033]
The sensor circuit (13) drives each displacement sensor (23), (29), (30) of the displacement detector (9), and based on the output of each displacement sensor (23), (29), (30), the rotating body Calculate the displacement in the Z-axis direction in (5) and the displacement in the X-axis direction and Y-axis direction in the upper and lower radial displacement sensor units (24) and (25), and AD-convert the displacement signal that is the result of the calculation To the DSP (18) through the device (20).
[0034]
Based on the digital displacement signal representing the displacement of the rotating body (5) input from the AD converter (20), the DSP (18) is connected to each electromagnet (26) of each magnetic bearing (6) (7) (8). (27) The excitation current signal for (28) is output to the magnetic bearing drive circuit (14) via the DA converter (21). The drive circuit (14) supplies the excitation current based on the excitation current signal from the DSP (18) to the electromagnets (26), (27), (28) of the corresponding magnetic bearings (6), (7), (8). Thereby, the rotating body (5) is supported in a non-contact manner at a predetermined target position.
[0035]
The DSP (18) also outputs a rotation speed command signal for the motor (10) to the inverter (15), and the inverter (15) controls the rotation speed of the motor (10) based on this signal. As a result, the rotating body (5) is rotated at high speed by the motor (10) while being supported in a non-contact manner at the target position by the magnetic bearings (6), (7), and (8).
[0036]
Excitation supplied to the electromagnets (26), (27), and (28) of each magnetic bearing (6), (7), and (8) by the controller (2) based on the output of the displacement sensors (23), (29), and (30) An electromagnet control means that controls the current is configured.
[0037]
FIG. 4 shows only the part related to the control of the pair of axial electromagnets (26a) and (26b) in the axial magnetic bearing (6) in the configuration of the controller (2). Next, the control of the pair of axial electromagnets (26a) and (26b) by the controller (2) will be described with reference to FIG.
[0038]
First, the sensor circuit (13) obtains the displacement of the rotating body (5) relative to the target position (= 0) in the Z-axis direction from the output signal of the axial displacement sensor (23), and a displacement signal ΔZ proportional to this displacement. Is output. The displacement signal ΔZ from the sensor circuit (13) is converted into a digital value by the AD converter (20) and input to the DSP (18). As will be described later, the DSP (18) outputs a pair of exciting current signals as control signals respectively corresponding to the pair of electromagnets (36) to the DA converter (21) based on the digital displacement signal ΔZ. . The first excitation current signal (Io + Ic) is converted into an analog signal by the DA converter (21), and the first excitation current signal (Io + Ic) is the first power amplifier (35) of the magnetic bearing drive circuit (14). The first power amplifier (35) amplifies the first excitation current signal (Io + Ic) and supplies an excitation current proportional thereto to the first electromagnet (26a). The second excitation current value (Io−Ic) is converted into an analog signal by the DA converter (21), and the second power of the magnetic bearing drive circuit (14) is converted into the second excitation current signal (Io−Ic). The second power amplifier (36) is supplied to the amplifier (36), amplifies the second excitation current signal (Io-Ic), and supplies an excitation current proportional thereto to the second electromagnet (26a). As a result, the rotating body (5) is supported at the target position in the Z-axis direction.
[0039]
FIG. 5 shows the operation of the DSP (18) as a functional block in the controller (2) shown in FIG. The DSP (18) functionally includes a control current calculation means (37), an identification means (32), an addition means (33), and an excitation current calculation means (38). Based on the displacement signal ΔZ from the AD converter (20), the control current calculation means (37) calculates a control current value Ico for the electromagnets (26a) and (26b) by, for example, PID calculation. The identification means (32) outputs a digital excitation signal S for exciting the rotating body (5) to the addition means (33). The adding means (33) adds the excitation signal S from the discriminating means (32) to the control current value Ico from the control current calculating means (37) to obtain a new control current value Ic. Output to excitation current calculation means (38). Except at the time of identifying the machine body (1), which will be described later, the excitation signal S is 0, and the control current value Ic that is the output of the adding means (33) is the output of the control current calculating means (37). Is equal to the control current value Ico. The excitation current calculation means (38) adds the control current value Ic from the addition means (33) to the bias current value Io stored in the table (34) of the flash memory (19), and the value obtained as a result (Io + Ic) is output to the DA converter (21) as the first exciting current value, and the control current value Ic is subtracted from the bias current value Io, and the resulting value (Io-Ic) is 2 excitation current value is output to the DA converter (21).
[0040]
FIG. 6 shows only the part related to the control of the pair of radial electromagnets (27a) and (27b) in the X-axis direction in the upper radial magnetic bearing (7) in the configuration of the controller (2). In this case, the sensor circuit (13) subtracts the other output signal from one output signal of the pair of radial position sensors (29a) (29b) in the X-axis direction of the upper radial position sensor unit (24). As a result, the displacement of the rotating body (5) with respect to the target position (= 0) in the X-axis direction in the upper radial magnetic bearing (7) is obtained, and a displacement signal ΔX proportional to this displacement is output. The displacement signal ΔX from the sensor circuit (13) is converted into a digital value (digital displacement signal) by the AD converter (20) and input to the DSP (18). The rest is the same as in the case of FIG. 4, and corresponding portions are denoted by the same reference numerals. In this case, the identification means (32) and the addition means (33) of FIG. 5 need not be provided in the DSP (18), and the control current value Ico from the control current calculation means (37) is directly used as the excitation current calculation. You may make it input into a means (38).
[0041]
A part related to control of a pair of radial electromagnets (27c) (27d) in the Y-axis direction in the upper radial magnetic bearing (7), a pair of radial electromagnets (28a) in the X-axis direction in the lower radial magnetic bearing (8) The same applies to the part relating to the control of) and 28b and the part relating to the control of the pair of radial electromagnets 28c and 28d in the Y-axis direction.
[0042]
In the above magnetic bearing device, when the controller (2) is not powered, the magnetic bearings (6), (7), (8) and the motor (10) are not driven and the rotating body (5) Is mechanically supported by the protective bearings (11) and (12) and stopped.
[0043]
When the controller (2) is powered on, the machine body (1) is identified by the identification means (32) of the DSP (18) as follows.
[0044]
When the controller (2) is turned on, the exciting current of the electromagnets (26) (27) (28) of each magnetic bearing (6) (7) (8) is first used using the temporary control parameters for identification. By controlling this, the rotating body (5) is supported in a non-contact manner at a predetermined target position. Thereafter, the rotating body (5) is vibrated in the Z-axis direction, and the type of the machine body (1) is identified based on the response state of the rotating body (5) in the Z-axis direction at that time. Then, a control parameter for operation corresponding to the identification result is selected, and thereafter, the magnetic bearings (6), (7), and (8) are controlled using the control parameter.
[0045]
Next, with reference to FIG. 4, FIG. 5, and FIG. 7, the operation of the portion related to the control of the axial magnetic bearing (6) of the DSP (18) at the time of identification will be described in more detail. Fig. 7 shows the frequency response in the control axis direction of the rotating body (5), that is, the gain characteristic in the Z-axis direction of the rotating body (5) when the rotating body (5) is vibrated in the Z-axis direction. The horizontal axis represents the frequency f, and the vertical axis represents the gain G.
[0046]
When the controller (2) is turned on, the identification means (32) first sets the excitation signal S to 0 and reads the temporary control parameters for identification from the flash memory (19). This is set at a predetermined position in the flash memory (19). When the set of the excitation signal S and the control parameter is completed, the control current calculation means (37) calculates the control current value Ico as described above based on the displacement signal ΔZ using the temporary control parameter. Then, the adding means (33) adds the excitation signal S to the control current value Ico from the control current calculating means (37) to obtain a new control current value Ic. At this time, since the excitation signal S is set to 0, the control current value Ic is equal to the control current value Ico. After that, as described above, the rotating body (5) is supported in a non-contact manner at a predetermined target position in the Z-axis direction using a temporary control parameter.
[0047]
When the rotating body (5) is supported in a non-contact manner in this way, the identification means (32) reads the sine wave signal data stored in the identification signal table of the flash memory (19) at a constant cycle. This is output to the adding means (33) as a vibration signal S. As a result, the control current value Ic calculated by the adding means (33) is obtained by adding a sine wave signal having a constant frequency to the control current value Ico from the control current calculating means (37). The excitation current supplied to the pair of electromagnets (26a) and (26b) is obtained by adding a sine wave signal to the excitation current during normal control. This sine wave signal causes the rotating body (5) to move in the Z-axis direction. Is excited. The discriminating means (32) is one of the displacement signal ΔZ which is an input signal of the DSP (18) and one of the output signals of the DSP (18) while outputting the data of the sine wave signal as the excitation signal S. Based on the first excitation current value (Io + Ic) from a certain excitation current calculation means (38), the gain characteristic at that time is examined, and based on this, the type of the machine body (1) is identified.
[0048]
The gain characteristic in the Z-axis direction of the rotator (5) when the rotator (5) is vibrated in the Z-axis direction is as shown in FIG. 7, which varies depending on the type of the machine body (1). In FIG. 7, A indicates the gain characteristics in the case of the machine main body (1) of type A, B indicates the case of the machine main body (1) of type B, and C indicates the gain characteristics in the case of the machine main body (1) of type C. . In such a case, for example, by obtaining the gain in the Z-axis direction when the rotating body (5) is vibrated at a constant frequency fo, the machine body (1) can be any of A, B, and C. Can be identified.
[0049]
When the identification of the machine main body (1) is completed, the identification means (32) reads the control parameter corresponding to the format of the machine main body (1) of the identification result from the table of the flash memory (19), and reads the control parameter in the predetermined flash memory. At the same time, the vibration signal S is set to 0 again. Thus, the rotating body (5) is supported in a non-contact manner at a predetermined target position using control parameters corresponding to the type of the machine body (1). If the rotating body (5) is supported in a non-contact manner in this way, the motor (10) is driven and the rotating body (5) is rotated at a high speed.
[0050]
Although FIG. 7 shows a case where there are three types of the machine main body (1), even when there are two or four or more types of machine main body (1), these can be identified in the same manner.
[0051]
In the above embodiment, the rotating body (5) is vibrated by adding a sine wave signal to the control current value Ico from the control current calculation means (37). The rotating body (5) can also be vibrated by adding a sine wave signal to each of the two excitation current values (Io + Ic) and (Io−Ic).
[0052]
In the above embodiment, an example in which the type of the machine body (1) is identified by adding a sine wave signal having a constant frequency to the control current value Ico and vibrating the rotating body (5) is shown. The machine body (1) type can also be identified by adding a variable frequency sine wave signal to the current value Ico to vibrate the rotor (5) and examining the response status of the rotor (5) at that time. can do.
[0053]
When adding variable frequency sine wave signals, when identifying the machine body (1), for example, the identification means (32) is stored in the identification signal table of the flash memory (19) of the controller (2). The sine wave signal data is read at a cycle corresponding to the requested frequency and output to the adding means (33).
[0054]
In the above-described embodiment, the DSP (18) uses the excitation data stored in the identification signal table of the flash memory (19), and the rotating means (5) by the identifying means (32) and the adding means (33). However, it is also possible to vibrate the rotating body (5) using a mechanical vibration device as the vibration means.
[0056]
In the above embodiment, the rotating body (5) is vibrated in the Z-axis direction to identify the type of the machine body (1). However, the rotating body (5) is vibrated in the X-axis direction, or in the Y-axis direction. The type of the machine body (1) can be identified by shaking. In addition, the type of the machine body (1) can be identified by exciting the rotating body (5) in any two directions of the three control axes of the X, Y and Z axes. You can also do it. Further, the type of the machine main body (1) can be identified by vibrating the rotating body (5) for each of the three control axes.
[0057]
As described above, the magnetic bearing device includes a vertical type in which the rotating body (5) is vertically supported and a horizontal type in which the rotating body is horizontally supported. It can also be applied to a bearing device. Note that the response status of the rotating body when the rotating body is vibrated varies for each control axis between the vertical type and the horizontal type, but in either type, the response status depends on the machine body type. Changes so that the type of machine body can be identified. Usually, since it is known in advance whether the magnetic bearing device is a vertical type or a horizontal type, a controller corresponding to the type may be used. Alternatively, a set of control parameters for vertical type (temporary control parameters and a plurality of sets of operation control parameters) and a set of control parameters for horizontal type are stored in one controller, and the type of magnetic bearing device is stored. Depending on the above, a set of corresponding control parameters may be selected. Further, when the type of the magnetic bearing device is not known, for example, the type (posture) of the magnetic bearing device is automatically determined by a method as described in JP-A-9-166139, Thereafter, the machine body can be identified as described above.
[0058]
In the above embodiment, the inner rotor type magnetic bearing device that rotates inside the casing (4) in which the rotating body (5) is a fixed part is shown, but the present invention rotates the rotating body outside the fixed part. The present invention can also be applied to an outer rotor type magnetic bearing device.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view of a main part of a mechanical part of a magnetic bearing device showing an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the same.
FIG. 3 is a block diagram showing an example of an electrical configuration of the magnetic bearing device.
4 is a block diagram showing a portion related to a pair of axial electromagnets of the controller of FIG. 3; FIG.
FIG. 5 is a block diagram showing functions of the DSP portion of FIG. 4;
6 is a block diagram showing a portion related to a pair of radial electromagnets of the controller of FIG. 3; FIG.
FIG. 7 is a graph illustrating an example of gain characteristics of a rotating body when identifying the type of a machine body.
[Explanation of symbols]
(1) Machine body
(2) Controller
(5) Rotating body
(6) Axial magnetic bearing
(7) (8) Radial magnetic bearing
(18) Digital signal processor (DSP)
(19) Flash memory
(23) Axial displacement sensor
(26a) (26b) Axial electromagnet
(27a) (27b) (27c) (27d) Radial electromagnet
(28a) (28b) (28c) (28d) Radial electromagnet
(29a) (29b) (29c) (29d) Radial displacement sensor
(30a) (30b) (30c) (30d) Radial displacement sensor
(32) Identification means

Claims (4)

A plurality of displacement sensors for detecting the displacement of the rotating body, a machine main body having a plurality of sets of magnetic bearings that support the rotating body in a non-contact manner at a predetermined target position by a magnetic attraction force of an electromagnet that forms a pair; A control type magnetic bearing device comprising: a controller having an electromagnet control means for controlling an exciting current supplied to the electromagnet based on an output of the displacement sensor used;
A software program in which the electromagnet control means outputs a digital control signal for controlling the excitation current based on a digital displacement signal representing the displacement of the rotating body obtained from the output of the displacement sensor using the control parameter. And a non-volatile storage device, and the non-volatile storage device includes a provisional control parameter for identification and a plurality of sets of operation control parameters corresponding to each type of the machine body. And the digital processing means comprises identification means for identifying the type of the machine body and selecting the control parameter corresponding to the identification result from the nonvolatile storage device, the identification means comprising the identification means, vibrated the rotating body after the non-contact support the rotary body to a predetermined target position by using the control parameters of the temporary identification Controlled magnetic bearing device, characterized in that it identifies the type of the machine body on the basis of the response state of the rotating body in this case. The identification means vibrates the rotating body by adding a predetermined digital identification signal to the digital control signal, and obtains the response status of the rotating body from the digital displacement signal at that time. The control type magnetic bearing device according to claim 1, wherein: 3. The control type magnetic bearing device according to claim 2 , wherein the digital identification signal is a sine wave signal having a constant frequency. 3. The control type magnetic bearing device according to claim 2 , wherein the digital identification signal is a sine wave signal having a variable frequency.

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