The present disclosure relates to a device and a method for inhibiting vibration of a rotor, and more specifically relates to a device and a method for inhibiting vibration of a low temperature superconducting magnetic suspension spherical rotor.
Some superconductors not only have a zero-resistance effect but also have a Meissner effect. The superconductor may be considered as a perfect diamagnet. Magnetic flux of an external magnetic field can not enter into an interior of the superconductor but are parallel to a surface of the superconductor. A magnetic field direction generated by a superconducting current induced on the surface of the superconductor is just opposite to that of the external magnetic field. The two magnetic fields interact to generate a magnetic thrust. The superconducting rotor can be suspended and rotated, by means of the Meissner effect of the superconductor, and the superconducting rotor may be operated stably without energy loss. Therefore, a variety of precision instruments developed with superconducting characteristics is highly precise and has a quite low energy consumption.
Due to limitations from processing technologies, it is quite difficult to obtain an absolute perfect rotor, and practically there exist various processing variations, which mainly involves two aspects, that is, a mass of the rotor is eccentric and a surface of the rotor is not a perfect sphere. The mass eccentricity of the rotor makes a center of the mass not coincide with a centre of the sphere. Thus, when the rotor rotates about an axis extending through two poles; the rotor is simultaneously subject to a gravity force, an electro-magnetic suspension force, and an inertial centrifugal force, so as to make the rotor rotate eccentrically. As a rotational speed of the rotor is increased, vibration of the rotor is continuously increased, and vibration amplitude thereof is continuously increased. When the rotational speed of the rotor is close to a critical rotational speed, the rotor will generate the strongest vibration, and the amplitude reaches a maximum value. An operating rotational speed of the rotor is generally higher than one-order critical rotational speed of the rotor, and thus it is required for an effective means to inhibit vibration of the rotor during a process that the rotor starts, accelerates, and reaches the operating rotational speed. When vibration of the rotor is relatively strong, due to non-absolute homogeneity nature of the superconducting material, the rotor is accompanied with capturing magnetic flux and alternative current loss under vibration, thereby affecting superconducting diamagnetism of the rotor, so that supporting suspension stability and supporting control precision of the superconducting rotor are decreased. A gap between the superconducting rotor and an inner wall of a rotor cavity is generally quite small. As vibration of the rotor is increased, increment of vibration amplitude and vibration energy may cause the superconducting rotor to transiently lose stability, yielding a phenomenon that the superconducting rotor scrapes against the inner wall of the rotor cavity, and thus scratches are formed on an outer surface of the rotor and the inner wall of the rotor cavity, and thus they can no longer be used. In a serious case, it may be possible for the rotor to fall down after scraping and thus damage the system. Therefore, inhibiting vibration during acceleration and deceleration of the rotor is one of key technologies to be urgently solved in research on operation of the superconducting rotor, and effectively controlling vibration of the rotor is also one of necessary conditions with which the superconducting rotor can operate normally and safely.
In order to overcome the defects as mentioned in prior arts so as to effectively inhibit vibration of a superconducting spherical rotor, the present disclosure provides a device and a method for inhibiting vibration of a low temperature superconducting magnetic suspension spherical rotor. The device for inhibiting vibration of the rotor of the present disclosure has a simple structure and has low energy consumption, the method is simple, has a good effect on controlling vibration of the rotor, and can effectively ensure a safe operation of the rotor.
The device of the present disclosure comprises a rotor cavity housing, lateral coils, a rotor top plane, a superconducting rotor, a copper plate, pole shoes, a z-axial vibration measuring sensor, an x-axial vibration measuring sensor, a y-axial vibration measuring sensor, and a copper ring. Inner surfaces of the pole shoes are spherical, the two annular pole shoes are up-down symmetrically disposed so as to form a rotor cavity in which the superconducting rotor is positioned. The two annular lateral coils, namely an upper lateral coil and a lower lateral coil, are closely adjacent to and fixed to an outer cylindrical surface of the rotor cavity housing, respectively. The copper plate with a circular shape is fixed to an upper end face of the rotor cavity housing. The z-axial vibration measuring sensor is fixed to a central region of the copper plate, and an optical axis of the z-axial vibration measuring sensor is perpendicular to the circular rotor top plane, and the z-axial vibration measuring sensor is used to measure a vibration amplitude of the rotor along a z-coordinate axis. The x-axial vibration measuring sensor and the y-axial vibration measuring sensor are respectively mounted on the copper ring in an equatorial plane along an x-coordinate axis and a y-coordinate axis respectively, and optical axes of the x-axial vibration measuring sensor and the y-axial vibration measuring sensor are parallel to the equatorial plane of the rotor and are directed towards a centre of the sphere, and the x-axial vibration measuring sensor and the y-axial vibration measuring sensor are used to measure vibration amplitudes of the rotor along the x-coordinate axis and the y-coordinate axis respectively. A gap between the superconducting rotor and the rotor cavity is in a range of 0.3 mm-0.5 mm when the superconducting rotor is centrally suspended.
According to the present disclosure, a method for inhibiting vibration of a superconducting magnetic suspension rotor comprising steps of: obtaining rotational speed-vibration amplitude curves of the rotor of the above-mentioned device under a plurality of supporting rigidities; then obtaining, according to the rotational speed-vibration amplitude curves of the rotor, a low vibration amplitude by selecting a predetermined supporting rigidity under a predetermined rotational speed under the plurality of supporting rigidities; wherein the plurality of supporting rigidities are realized by applying different currents to the upper lateral coil and the lower lateral coil.
The method of the present disclosure may include the following steps:
1. firstly, applying predetermined currents to the upper lateral coil and the lower lateral coil respectively, so as to allow the superconducting rotor to suspend centrally within the rotor cavity and allow the superconducting rotor to be subjected to a certain supporting rigidity K1; after the conducting rotor starts and accelerates, measuring vibration amplitudes of the superconducting rotor in the directions of x-coordinate axis, y-coordinate axis and z-coordinate axis by the x-axial vibration measuring sensor, the y-axial vibration measuring sensor, and the z-axial vibration measuring sensor respectively, and calculating a resultant vibration amplitude of the superconducting rotor by means of performing a summing operation to a vibration vector along the x-coordinate axis, a vibration vector along the y-coordinate axis, and a vibration vector along the z-coordinate axis, so that a vibration amplitude curve during a process that the superconducting rotor (4) starts, accelerates, and reaches an operating rotational speed is obtained and indicated as L1;
2. then, applying certain currents to the upper lateral coil and the lower lateral coil so as to allow the superconducting rotor to suspend centrally within the rotor cavity and allow the superconducting rotor to be subjected to a certain supporting rigidity K2 which is larger than K1; after the conducting rotor starts and accelerates, measuring vibration amplitudes of the superconducting rotor in the directions of x-coordinate axis, y-coordinate axis and z-coordinate axis by the x-axial vibration measuring sensor, the y-axial vibration measuring sensor, and the z-axial vibration measuring sensor respectively, and calculating a resultant vibration amplitude of the superconducting rotor by means of performing a summing operation to a vibration vector along the x-coordinate axis, a vibration vector along the y-coordinate axis, and a vibration vector along the z-coordinate axis, so that a vibration amplitude curve during a process that the superconducting rotor starts, accelerates, and reaches an operating rotational speed is obtained and indicated as L2; an intersection point between the curve L1 and the curve L2 in a coordinate system consisting of a rotational speed coordinate axis and a vibration amplitude coordinate axis being C, a rotational speed of the superconducting rotor corresponding to the point C being ωB, a vibration amplitude of the superconducting rotor corresponding to the point C being AB; and
3. finally, when the superconducting rotor starts and accelerates, firstly letting the superconducting rotor to be subjected to the supporting rigidity K2, and when the rotor accelerates to ωB, changing the currents flowing through the upper lateral coil and the lower lateral coil to thus change the supporting rigidity of the superconducting rotor to K1 from K2 so that the vibration amplitude of the superconducting rotor is not larger than AB during the whole acceleration process.
The method for inhibiting vibration of a superconducting magnetic suspension rotor of the present disclosure may be: when the superconducting rotor starts, a current of 16-17 A and a current of 18-18.5 A are applied to the upper lateral coil and the lower lateral coil, respectively; when the rotor accelerates and reaches 1200-1250 RPM, the current flowing through the upper lateral coil and the current flowing through the lower lateral coil are rapidly changed to 8-8.5 A and 13-13.5 A, so that the vibration amplitude of the superconducting rotor is not larger than 0.1-0.2 mm during the whole acceleration process.
Hereinafter the present invention will be further described with reference to the drawings and specific embodiments.
As shown in
As shown in
By supplying appropriate electric currents through the upper lateral coil 2 and the lower lateral coil 13, the superconducting rotor 4 can be suspended centrally within the rotor cavity 10. In this way, the superconducting rotor 4 can rotate in the rotor cavity 10, without friction, after being activated and accelerated.
Hereinafter, a method for inhibiting vibration of a rotor, by means of the device for inhibiting vibration of the superconducting magnetic suspension in accordance with the present invention as above, will be described with reference to
As shown in
The method according to the exemplary example is realized by obtaining two supporting rigidity-rotational speed-vibration amplitude curves in advance and comprises the following steps.
Stage 1: firstly, a first current (for example a current of 8-8.5 A) is applied to the upper lateral coil 2 and a second current (for example a current of 13-13.5 A) is applied to the lower lateral coil 13 so as to allow the superconducting rotor 4 to suspend centrally within the rotor cavity 10 and allow the superconducting rotor 4 to be subjected to a first supporting rigidity K1. After the conducting rotor 4 starts and accelerates, magnitudes of vibration amplitudes of the superconducting rotor 4 are measured by the x-axial vibration measuring sensor 8, the y-axial vibration measuring sensor 9, and the z-axial vibration measuring sensor 7. A summing operation is performed to the x, y, z-axial vibration amplitudes, i.e., calculating a square root of a sum of a square of the x-axial vibration amplitude, a square of the y-axial vibration amplitude, and a square of the z-axial vibration amplitude as a vibration amplitude of the superconducting rotor 4, so that a vibration amplitude curve during the process that the superconducting rotor starts, accelerates, and reaches the operating rotational speed is obtained and indicated as L1.
Stage 2: after that, similarly, a third current (for example a current of 16-17 A) is applied to the upper lateral coil 2 and a fourth current (for example a current of 18-18.5 A) is applied to the lower lateral coil 13 so as to allow the superconducting rotor 4 to suspend centrally within the rotor cavity 10 and allow the superconducting rotor 4 to be subjected to a first supporting rigidity K2 which is larger than K1. After the conducting rotor 4 starts and accelerates, magnitudes of vibration amplitudes of the superconducting rotor 4 in the x, y, z-axial directions are measured by respectively the x-axial vibration measuring sensor 8, the y-axial vibration measuring sensor 9, and the z-axial vibration measuring sensor 7. The summing operation is performed to the x, y, z-axial vibration vectors and the result is used as a resultant vibration amplitude of the superconducting rotor 4, so that a vibration amplitude curve during a process that the superconducting rotor starts, accelerates, and reaches the operating rotational speed is obtained and indicated as L2. An intersection point between the curve L1 and the curve L2 in a coordinate system consisting of a rotational speed coordinate axis and a vibration amplitude coordinate axis is indicated as C, and a rotational speed of the superconducting rotor 4 corresponding to the C is ωB. In an exemplary embodiment, ωB has a value of 1200 RPM, and a corresponding vibration amplitude AB is 0.1-0.2 mm.
Stage 3: finally, when the superconducting rotor 4 starts and accelerates, the superconducting rotor 4 is firstly subjected to the supporting rigidity K2, and when the rotor accelerates to 1200-1250 RPM, the current flowing through the upper lateral coil 2 is rapidly changed to 8-8.5 A and the current flowing through the lower lateral coil 13 is changed to 13-13.5 A, so that the supporting rigidity of the superconducting rotor 4 is changed to K1 from K2. In this way, the vibration amplitude of the superconducting rotor 4 is not larger than AB during the whole acceleration process, that is, the vibration amplitude is not larger than 0.1-0.2 mm. Based on a fact that a gap between the superconducting rotor 4 and the rotor cavity 10 is in a range of 0.3-0.5 mm, such a vibration of the superconducting rotor 4 during acceleration will not cause the superconducting rotor 4 to scrape against the rotor 1, so that safety is effectively ensured during acceleration of the superconducting rotor 4.
Although the method for performing control by obtaining two supporting rigidity-rotational speed-vibration amplitude curves in advance is described above, it is easily understood for a person skilled in the art that the method may be further refined by obtaining more supporting rigidity-rotational speed-vibration amplitude curves in advance.
As shown in
Number | Date | Country | Kind |
---|---|---|---|
2010 1 0276940 | Sep 2010 | CN | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/CN2011/078981 | 8/26/2011 | WO | 00 | 5/29/2013 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2012/031528 | 3/15/2012 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3722288 | Weber | Mar 1973 | A |
4697128 | Matsushita | Sep 1987 | A |
4961352 | Downer | Oct 1990 | A |
5256637 | Rao | Oct 1993 | A |
5789838 | Gondhalekar | Aug 1998 | A |
Number | Date | Country |
---|---|---|
2484547 | Apr 2002 | CN |
101113896 | Jan 2008 | CN |
101951208 | Jan 2011 | CN |
2727200 | May 1996 | FR |
01167675 | Jul 1989 | JP |
Entry |
---|
Cui et al., Machine Translation of CN101113896, Jan. 2008. |
Hu et al., Study of an Optical Readout System for Angular Position Detection of the Spin Axis of Superconducting Rotor in Cryogenic Environment, Chinese Journal of Low Temperature Physics, Nov. 2005, pp. 636-638, vol. 27, No. 5. (English-language Abstract attached). |
Number | Date | Country | |
---|---|---|---|
20130285624 A1 | Oct 2013 | US |