CN205593500U - Axial displacement detection device and magnetic suspension bearing - Google Patents

Abstract

The utility model discloses an axial displacement detection device and magnetic suspension bearing relates to and measures technical field. The device includes: the first sensor for based on the first signal of telecommunication of radial displacement output of being surveyed the non - inclined plane of component, the second sensor for based on the radial displacement output second signal of telecommunication of being surveyed the component inclined plane, axial displacement calculating unit for according to the angle of inclination on the first signal of telecommunication, the second signal of telecommunication and quilt survey component inclined plane, calculate the axial displacement who is surveyed the component, wherein, the axial surface of being surveyed the component has inclined plane and non - inclined plane, and a sensor settings is being surveyed the non - inclined plane of component top, and the 2nd sensor settings is being surveyed component inclined plane top. Promptly the utility model discloses a set up the inclined plane, the radial displacement who surveys the component according to the quilt calculates axial displacement, has improved the precision that axial displacement detected.

Description

A kind of device for detecting axial displacement and magnetic suspension bearing

Technical field

This utility model relates to field of measuring technique, particularly relates to a kind of device for detecting axial displacement And magnetic suspension bearing.

Background technology

In magnetic suspension bearing control system, axial displacement mainly has two kinds of detection methods.A kind of Method is as it is shown in figure 1, overlap a detection dish 120 on axle 110, and axial sensor 130 is led to Cross and measure the axially-movable of detection dish to determine the axial displacement of axle.The error brought due to assembling, Detection dish and centrage 140 out of plumb of axle, so may result in axle axial in rotary course Displacement has fluctuation, and detection dish is radius the best part on whole rotor, causes assemble flow Relatively complicated；Another kind of method is as in figure 2 it is shown, displacement transducer 210 is just to rotor 220 axle End 230 installation, it is applicable to most application scenario, but is not intended to some special applications Occasion.The such as rotor of the equipment such as centrifugal water pump, cfentrifugal blower, its functional part is big It is arranged on axle head more, and is cantilever design, now make displacement transducer due to reasons such as structures Working rotor axial end is just installed by inconvenience, simultaneously in order to reduce rotor expanded by heating to function part The impact of part position, sensor needs close proximity to functional part, and can not be arranged on rotor Inoperative axle head.This detection method is unfavorable for axial sensor and the integrated place of radial transducer Reason, increases structure axial space.It addition, because technique and assembling factor also bring along detection by mistake Difference.

Utility model content

One to be solved in the utility model technical problem is that conventional axial displacement detecting precision not High.

The present invention to solve the technical problem that the structure including rotor is complicated further, is not easy to peace Dress, in the case of the axial limited space of rotating machinery, axially take up room big problem.

According to this utility model on the one hand, it is provided that a kind of device for detecting axial displacement, detected element Axial surface there is inclined plane and non-inclined face, this device includes: first sensor, is used for Radial displacement based on detected element non-inclined face exports first signal of telecommunication；Second sensor, uses Second signal of telecommunication is exported in radial displacement based on detected element inclined plane；Axially displacement calculates single Unit, is used for according to first signal of telecommunication, second signal of telecommunication and the inclination angle of detected element inclined plane, Calculate the axial displacement of detected element；Wherein, first sensor is arranged on detected element non-inclined Above face, the second sensor is arranged on above detected element inclined plane.

Further, first signal of telecommunication and second signal of telecommunication are voltage signal；Axially displacement calculates Unit is for according to formulaCalculate the axial displacement of detected element；Wherein, U_r It is first signal of telecommunication, U_zBeing second signal of telecommunication, φ is the inclination angle of inclined plane, k₁It it is the first sensing The sensitivity parameter of device, k₂It it is the sensitivity parameter of the second sensor.

Further, first sensor and the second sensor are arranged on probe ring, and first passes The probe of sensor and the mounting distance of the probe of the second sensor are more than threshold value.

Further, first sensor and the second sensor are current vortex sensor.

Further, the probe of first sensor is all directed at probe ring with the probe of the second sensor Circle central axis, and installation direction is consistent.

Further, the axial length of inclined plane is more than the maximum axial displacement of detected element.

Further, the inclination angle of detected element inclined plane is preset value.

Further, the inclination angle of detected element inclined plane is 0 °～90 °.

Further, detected element is the rotor of magnetic suspension bearing.

According to another aspect of the present utility model, also provide for a kind of magnetic suspension bearing, including: turn Son, the axial surface of rotor is provided with inclined plane and non-inclined face.

Further, any of the above-described device for detecting axial displacement is also included.

Compared with prior art, the axial surface of this utility model detected element have inclined plane and Non-inclined face, and be provided with at least two sensor in a device, one of them sensor based on The radial displacement in detected element non-inclined face exports first signal of telecommunication, and another sensor is based on quilt Survey organs incline face radial displacement export second signal of telecommunication, further according to first signal of telecommunication, second The signal of telecommunication and the inclination angle of detected element inclined plane, calculate the axial displacement of detected element.The most logical Cross and inclined plane is set, calculate axial displacement according to the radial displacement of detected element, improve axially The precision of displacement detecting.

Further, the simple in construction of rotor, it is simple to install, in the axial limited space of rotating machinery In the case of, it is possible to save part axial space.

By detailed description to exemplary embodiment of the present utility model referring to the drawings, this The further feature of utility model and advantage thereof will be made apparent from.

Accompanying drawing explanation

The accompanying drawing of the part constituting description describes embodiment of the present utility model, and connects It is used for together with description explaining principle of the present utility model.

Referring to the drawings, according to detailed description below, this practicality can be more clearly understood from new Type, wherein:

Fig. 1 is the structural representation that prior art detects an embodiment of axial displacement.

Fig. 2 is the structural representation that prior art detects another embodiment of axial displacement.

Fig. 3 is the structural representation of an embodiment of this utility model device for detecting axial displacement Figure.

Fig. 4 is sensor mounting location schematic diagram in one embodiment of this utility model.

Fig. 5 is the structural representation of another embodiment of this utility model device for detecting axial displacement Figure.

Fig. 6 is that in one embodiment of this utility model, current vortex sensor detection magnetic suspension shaft is forwarded The operation principle schematic diagram of sub-displacement.

Fig. 7 A is that in one embodiment of this utility model, device for detecting axial displacement operation principle is shown It is intended to.

Fig. 7 B is that in one embodiment of this utility model, device for detecting axial displacement operation principle is put Big schematic diagram.

Fig. 8 is the flow process signal of an embodiment of the axial displacement detecting method of this utility model Figure.

Fig. 9 is that the flow process of a specific embodiment of the axial displacement detecting method of this utility model is shown It is intended to.

Figure 10 is the structural representation of an embodiment of the rotor of this utility model magnetic suspension bearing Figure.

Detailed description of the invention

Various exemplary embodiment of the present utility model is described in detail now with reference to accompanying drawing.Should Note that unless specifically stated otherwise, the parts illustrated the most in these embodiments and step Positioned opposite, numerical expression and numerical value be not intended to scope of the present utility model.

Simultaneously, it should be appreciated that for the ease of describing, the chi of the various piece shown in accompanying drawing Very little is not to draw according to actual proportionate relationship.

Description only actually at least one exemplary embodiment is illustrative below, certainly Not as to this utility model and application thereof or any restriction of use.

May not make in detail for technology, method and apparatus known to person of ordinary skill in the relevant Thin discussion, but in the appropriate case, technology, method and apparatus should be considered to authorize description A part.

Shown here with in all examples discussed, any occurrence should be construed as merely Exemplary rather than conduct limits.Therefore, other example of exemplary embodiment can have There is different values.

It should also be noted that similar label and letter expression similar terms in following accompanying drawing, therefore, The most a certain Xiang Yi accompanying drawing is defined, then need not it is carried out in accompanying drawing subsequently Discussed further.

For making the purpose of this utility model, technical scheme and advantage clearer, below tie Close specific embodiment, and referring to the drawings, this utility model is further described.

Fig. 3 is the structural representation of an embodiment of this utility model device for detecting axial displacement Figure.This utility model goes out an inclined plane in the Surface Machining of detected element 300 in advance, wherein Detected element can be the rotor of bearing, and bearing is specifically as follows magnetic suspension bearing.Inclined plane can Think the inclined plane of depression, it is also possible to for protruding inclined plane, with the inclined plane of depression be below Example illustrates.It is provided above first sensor 311, for based on quilt in non-inclined face 310 The radial displacement surveying element non-inclined face exports first signal of telecommunication；It is provided above in inclined plane 320 Second sensor 321, exports the second telecommunications for radial displacement based on detected element inclined plane Number；Wherein first signal of telecommunication, second signal of telecommunication can be voltage signal, first sensor and Two sensings can be current vortex sensor.Axially displacement computing unit for according to first signal of telecommunication, Second signal of telecommunication and the inclination angle of detected element inclined plane, calculate the axial displacement of detected element, Wherein axially displacement computing unit marks the most in figure 3.

In one embodiment, the axial length L of the inclined plane of detected element is more than detected element Maximum axial displacement Zmax, i.e. in detected element in moving process, measure inclined plane Sensor is all the time in inclined plane axial length range.The inclination angle phi of detected element inclined plane is Preset value, it is suitable to keep, and gradient is little, may cause the displacement sensitivity that sensor is measured Low, gradient the most then causes range less than normal, and inclination angle can be such as 0 °～90 °, preferably model Enclosing is 10 °～80 °, 30 °～60 °, can be such as 30 ° with value, 40 °, 43 °, 45°、48°、50°、55°、60°。

Fig. 4 is sensor mounting location schematic diagram in one embodiment of this utility model.This enforcement In example, first sensor and the second sensing can be current vortex sensor, and installation site is Fig. 4 Shown in, 410 is the rotating shaft of bearing, and 420 is sensor probe ring, the probe of first sensor 430 and second probe 440 centrage of sensor be respectively aligned to the central principal axis of detected element. The distance on the surface that probe distance measures rotating shaft not can exceed that the range of sensor, and first passes The probe of sensor and the mounting distance of the probe of the second sensor are more than threshold value, it is to avoid two sensings Interference is produced between device.

In embodiment of the present utility model, the axial surface tool of detected element of the present utility model There are inclined plane and non-inclined face, and are provided with at least two sensor in a device, one of them Sensor radial displacement based on detected element non-inclined face exports first signal of telecommunication, and another passes Sensor radial displacement based on detected element inclined plane exports second signal of telecommunication, further according to the first electricity Signal, second signal of telecommunication and the inclination angle of detected element inclined plane, calculate the axial of detected element Displacement.I.e. calculate axial displacement according to the radial displacement of detected element, solve conventional axial position Move the problem bringing detection error because of technique and assembling factor.It addition, this utility model is not because Arranging detection dish, the most the end face at working shaft does not arranges sensor, is thus advantageous to sensor Integrated approach, increases structure axial space, it is simple to install.

In another embodiment of the present utility model, the first current vortex sensor 510 is for base Radial displacement in the non-inclined face of magnetic suspension bearing rotor exports the first voltage signal U_r.Second Current vortex sensor 520 is for the radial displacement output of inclined plane based on magnetic suspension bearing rotor Second voltage signal U_z.Axially displacement computing unit 530 is for according to formula Calculate the axial displacement of magnetic suspension bearing rotor.Wherein, k₁It it is the spirit of the first current vortex sensor Sensitivity parameter, k₂Being the sensitivity parameter of the second current vortex sensor, φ is the inclination angle of inclined plane. The sensitivity of sensor can be adjusted by the slope of inclined plane.

Current vortex sensor detects the operation principle of magnetic suspension bearing rotor displacement as shown in Figure 6, When probe coil 610 changes apart from distance x on detected body surface 620, can cause The equiva lent impedance of coil changes, and utilizes measuring circuit the change of impedance can be changed into voltage Signal U, and the different corresponding different voltage signals of displacement.

Such as, device for detecting axial displacement work during Fig. 7 A is one embodiment of this utility model Principle schematic, Fig. 7 B is the enlarged drawing of encircled portion in Fig. 7 A, if magnetic suspension shaft is forwarded The rotating shaft 710 of son is only axially producing displacement z, the then output of the first current vortex sensor 720 Will not change, now, the output voltage of the second current vortex sensor 730 is: U_z=k₂X, Wherein, x is the distance variable quantity of the second current vortex sensor 730 and inclined-plane, unit mm, U_z Representing the output voltage of the second current vortex sensor 730, unit is V, k₂It it is the second current vortex The sensitivity parameter of sensor 730, unit V/mm.Rotor is axial as seen from Figure 7 The relation of displacement z Yu x is z=x/tan φ, the unit of z be mm, φ be the inclination angle of inclined plane.

If the rotating shaft of magnetic suspension bearing rotor 710 is radially also producing movement, the second current vortex passes The exporting change of sensor 730 is the axial displacement by rotor and radial displacement superposition generation, now It is accomplished by realizing the decoupling of axial displacement and radial displacement by the first current vortex sensor 720. Second current vortex sensor 730 is output as: U_z=k₂(x+y), y represents rotor non-inclined face Radial displacement, if the sensitivity parameter of the first current vortex sensor 720 is k₁, output voltage is: U_r=k₁y。

The most each formula is carried out simultaneous, it can be deduced that the rotating shaft of the magnetic suspension bearing rotor of rotor The axial displacement of 710 is $z=(\frac{U_z}{k_2}-\frac{U_r}{k_1})/tan\mathrm{\φ}.$

If the rotating shaft of magnetic suspension bearing rotor 710 produces radial displacement, Still set up, now haveAxially displacement is 0.

In embodiment of the present utility model, by first sensor based on magnetic suspension bearing rotor The radial displacement in non-inclined face export the first voltage signal U_r, the second sensor is based on magnetic suspension The radial displacement of the inclined plane of bearing rotor exports the second voltage signal U_z, and utilize according to formulaCalculate the axial displacement of magnetic suspension bearing rotor.Radial displacement can be utilized real The now calculating of axially displacement.Further, conventional axial displacement is solved because of technique and assembling factor band The problem detecting error.It addition, this utility model is because being not provided with detection dish, do not exist simultaneously The end face of working shaft arranges sensor, is thus advantageous to sensor integrationization and processes, also simplify The structure of rotor, it is simple to install.In the case of the axial limited space of rotating machinery, it is possible to joint Save a part of space.

Fig. 8 is the flow process signal of an embodiment of the axial displacement detecting method of this utility model Figure.

In step 810, receive first sensor radial displacement based on detected element non-inclined face First signal of telecommunication of output.

In step 820, receive the radial displacement based on detected element inclined plane of the second sensor defeated Second signal of telecommunication gone out.

Step 810 and step 820 can occur in the process of implementation simultaneously.First telecommunications therein Number, second signal of telecommunication can be voltage signal, detected element can be the rotor of bearing, bearing Can be magnetic suspension bearing, first sensor and the second sensor be current vortex sensor.

In step 830, according to first signal of telecommunication, second signal of telecommunication and detected element inclined plane Inclination angle, calculates the axial displacement of detected element.

This utility model as it is shown on figure 3, in advance the Surface Machining in detected element 300 go out one Inclined plane.Inclined plane can be the inclined plane of depression, it is also possible to for protruding inclined plane, below Illustrate as a example by the inclined plane of depression.It is provided above first sensor in non-inclined face 310 311, it is provided above the second sensor 321 in inclined plane 320.The axle of the inclined plane of detected element To length L more than maximum axial displacement Zmax of detected element, i.e. moving in detected element During, measure the sensor of inclined plane all the time in inclined plane axial length range.Tested unit The inclination angle phi of part inclined plane is preset value, and it is suitable to keep, and gradient is little, may cause passing The displacement sensitivity that sensor is measured is low, and gradient the most then causes range less than normal, such as may be used in inclination angle Thinking 0 °～90 °, preferably scope is 10 °～80 °, 30 °～60 °, such as can be with value It it is 30 °, 40 °, 43 °, 45 °, 48 °, 50 °, 55 °, 60 °.

Fig. 4 is sensor mounting location schematic diagram in one embodiment of this utility model.This enforcement In example, first sensor and the second sensing can be current vortex sensor, and installation site is Fig. 4 Shown in, 410 is the rotating shaft of bearing, and 420 is sensor probe ring, the probe of first sensor 430 and second probe 440 centrage of sensor be respectively aligned to the central principal axis of detected element. The distance on the surface that probe distance measures rotating shaft not can exceed that the range of sensor, and first passes The probe of sensor and the mounting distance of the probe of the second sensor are more than threshold value, it is to avoid two sensings Interference is produced between device.

In embodiment of the present utility model, by arranging two sensors, one of them sensing Device radial displacement based on detected element non-inclined face exports first signal of telecommunication, another sensor Radial displacement based on detected element inclined plane exports second signal of telecommunication, further according to first signal of telecommunication, Second signal of telecommunication and the inclination angle of detected element inclined plane, calculate the axial displacement of detected element. I.e. calculate axial displacement according to the radial displacement of detected element, solve conventional axial displacement because of work The problem that skill and assembling factor bring detection error.It addition, this utility model is because being not provided with inspection Survey dish, the most the end face at working shaft does not arranges sensor, is thus advantageous to sensor integration Process, increase structure axial space, it is simple to install.

Fig. 9 is that the flow process of a specific embodiment of the axial displacement detecting method of this utility model is shown It is intended to.

In step 910, receive that the first current vortex sensor is based on magnetic suspension bearing rotor non-to incline First voltage signal U of the radial displacement output on inclined-plane_r。

In step 920, receive the second current vortex sensor inclination based on magnetic suspension bearing rotor Second voltage signal U of the radial displacement output in face_z。

Step 910 and step 920 can occur in the process of implementation simultaneously.

In step 930, according to formulaCalculate the axial of magnetic suspension bearing rotor Displacement.

Wherein, k₁It is the sensitivity parameter of the first current vortex sensor, k₂It is that the second current vortex passes The sensitivity parameter of sensor, φ is the inclination angle of inclined plane.The sensitivity of sensor can be by inclining The slope on inclined-plane is adjusted.

Current vortex sensor detects the operation principle of magnetic suspension bearing rotor displacement as shown in Figure 6, When probe coil 610 changes apart from distance x on detected body surface 620, can cause The equiva lent impedance of coil changes, and utilizes measuring circuit the change of impedance can be changed into voltage Signal U, and the different corresponding different voltage signals of displacement.

Such as, device for detecting axial displacement work during Fig. 7 A is one embodiment of this utility model Principle schematic, Fig. 7 B is the enlarged drawing of encircled portion in Fig. 7 A, if magnetic suspension shaft is forwarded The rotating shaft 710 of son is only axially producing displacement z, the then output of the first current vortex sensor 720 Will not change, now, the output voltage of the second current vortex sensor 730 is: U_z=k₂X, Wherein, x is the distance variable quantity of the second current vortex sensor 730 and inclined-plane, unit mm, U_z Representing the output voltage of the second current vortex sensor 730, unit is V, k₂It it is the second current vortex The sensitivity parameter of sensor 730, unit V/mm.Rotor is axial as seen from Figure 7 The relation of displacement z Yu x is z=x/tan φ, the unit of z be mm, φ be the inclination angle of inclined plane.

If the rotating shaft of magnetic suspension bearing rotor 710 is radially also producing movement, the second current vortex passes The exporting change of sensor 730 is the axial displacement by rotor and radial displacement superposition generation, now It is accomplished by realizing the decoupling of axial displacement and radial displacement by the first current vortex sensor 720. Second current vortex sensor 730 is output as: U_z=k₂(x+y), y represents rotor non-inclined face Radial displacement, if the sensitivity parameter of the first current vortex sensor 720 is k₁, output voltage is: U_r=k₁y。

The most each formula is carried out simultaneous, it can be deduced that the rotating shaft of the magnetic suspension bearing rotor of rotor The axial displacement of 710 is $z=(\frac{U_z}{k_2}-\frac{U_r}{k_1})/tan\mathrm{\φ}.$

If the rotating shaft of magnetic suspension bearing rotor 710 produces radial displacement, Still set up, now haveAxially displacement is 0.

In embodiment of the present utility model, by first sensor based on magnetic suspension bearing rotor The radial displacement in non-inclined face export the first voltage signal U_r, the second sensor is based on magnetic suspension The radial displacement of the inclined plane of bearing rotor exports the second voltage signal U_z, and utilize according to formulaCalculate the axial displacement of magnetic suspension bearing rotor.Radial displacement can be utilized real The now calculating of axially displacement.Further, conventional axial displacement is solved because of technique and assembling factor band The problem detecting error.It addition, this utility model is because being not provided with detection dish, do not exist simultaneously The end face of working shaft arranges sensor, is thus advantageous to sensor integrationization and processes, also simplify The structure of rotor, it is simple to install.In the case of the axial limited space of rotating machinery, it is possible to joint Save a part of space.

Figure 10 is the structural representation of an embodiment of the rotor of this utility model magnetic suspension bearing Figure.

1010 is the inclined plane of the rotor of magnetic suspension bearing, and 1020 is the rotor of magnetic suspension bearing Non-inclined face, 1030 is the rotating shaft of the rotor of magnetic suspension bearing.Inclined plane can be depression Inclined plane, it is also possible to for protruding inclined plane.In one embodiment, magnetic suspension bearing rotor The axial length L of inclined plane more than the maximum axial displacement of magnetic suspension bearing rotor.Inclined plane Inclination angle phi be preset value, it is suitable to keep, and inclination angle can be such as 0 °～90 °, excellent Selecting scope is 10 °～80 °, 30 °～60 °, can be such as 30 ° with value, 40 °, 43 °, 45°、48°、50°、55°、60°。

In one embodiment, magnetic suspension bearing of the present utility model also includes axial displacement detecting Device.Wherein, device for detecting axial displacement has been described in detail in the various embodiments described above, The most no longer it is expanded on further.

In this embodiment, the axial surface of magnetic suspension bearing rotor arranges inclined plane.? When carrying out axial displacement detecting, it is only necessary to two sensors, one of them sensor detection non-inclined The radial displacement output signal of telecommunication in face, the radial displacement output of another sensor detection inclined plane The signal of telecommunication, further according to two signals of telecommunication and the inclination angle of inclined plane, calculates turning of magnetic suspension bearing The axial displacement of son.Simplify the structure of rotor, solve conventional axial displacement because of technique and dress Join the problem that factor brings detection error.It addition, this utility model is when detecting axial displacement, Being not provided with detection dish, the most the end face at working shaft does not arranges sensor, is thus advantageous to sensing Device integrated approach, increases structure axial space, it is simple to install.

So far, this utility model is described in detail.Of the present utility model in order to avoid covering Design, does not describe details more known in the field.Those skilled in the art are according to above Description, completely it can be appreciated how implement technical scheme disclosed herein.

Although specific embodiments more of the present utility model having been carried out in detail by example Illustrate, but it should be appreciated by those skilled in the art, above example merely to illustrate, Rather than in order to limit scope of the present utility model.It should be appreciated by those skilled in the art, can In the case of without departing from scope and spirit of the present utility model, above example is modified. Scope of the present utility model is defined by the following claims.

Claims (11)

1. a device for detecting axial displacement, it is characterised in that the axial surface of detected element has inclined plane and non-inclined face, described device includes:

First sensor, exports first signal of telecommunication for radial displacement based on described detected element non-inclined face；

Second sensor, exports second signal of telecommunication for radial displacement based on described detected element inclined plane；

Axially displacement computing unit, for according to described first signal of telecommunication, described second signal of telecommunication and the inclination angle of described detected element inclined plane, calculates the axial displacement of described detected element；

Wherein, described first sensor is arranged on above described detected element non-inclined face, and described second sensor is arranged on above described detected element inclined plane.

Device the most according to claim 1, it is characterised in that described first signal of telecommunication and described second signal of telecommunication are voltage signal；

Described axial displacement computing unit is for according to formulaCalculate the axial displacement of described detected element；

Wherein, U_rFor described first signal of telecommunication, U_zFor described second signal of telecommunication, φ is the inclination angle of described inclined plane, k₁For the sensitivity parameter of described first sensor, k₂Sensitivity parameter for described second sensor.

Device the most according to claim 1 and 2, it is characterised in that described first sensor and described second sensor are arranged on probe ring, and the mounting distance of the probe of the probe of described first sensor and described second sensor is more than threshold value.

Device the most according to claim 1 and 2, it is characterised in that the probe of described first sensor is all directed at the circle central axis of probe ring with the probe of the second sensor, and installation direction is consistent.

Device the most according to claim 1 and 2, it is characterised in that the axial length of described inclined plane is more than the maximum axial displacement of described detected element.

Device the most according to claim 1 and 2, it is characterised in that the inclination angle of described detected element inclined plane is preset value.

Device the most according to claim 6, it is characterised in that the inclination angle of described detected element inclined plane is 0 °～90 °.

Device the most according to claim 1 and 2, it is characterised in that described detected element is the rotor of magnetic suspension bearing；

Or

Described first sensor and the second sensor are current vortex sensor.

9. a magnetic suspension bearing, it is characterised in that including:

Detected element；The axial surface of wherein said detected element is provided with inclined plane and non-inclined face, and wherein said detected element is rotor.

10. a magnetic suspension bearing, it is characterised in that also include the device for detecting axial displacement as described in claim 1-8 is arbitrary.

11. magnetic suspension bearings according to claim 10, it is characterised in that also include:

Rotor, wherein, the axial surface of described rotor is provided with inclined plane and non-inclined face.