CN101251149A - Low power consumption 5-freedom permanent magnetism off-set magnetic suspension bearing system - Google Patents
Low power consumption 5-freedom permanent magnetism off-set magnetic suspension bearing system Download PDFInfo
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- CN101251149A CN101251149A CNA2008100198144A CN200810019814A CN101251149A CN 101251149 A CN101251149 A CN 101251149A CN A2008100198144 A CNA2008100198144 A CN A2008100198144A CN 200810019814 A CN200810019814 A CN 200810019814A CN 101251149 A CN101251149 A CN 101251149A
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- freedom
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- permanent magnet
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16C—SHAFTS; FLEXIBLE SHAFTS; ELEMENTS OR CRANKSHAFT MECHANISMS; ROTARY BODIES OTHER THAN GEARING ELEMENTS; BEARINGS
- F16C32/00—Bearings not otherwise provided for
- F16C32/04—Bearings not otherwise provided for using magnetic or electric supporting means
- F16C32/0406—Magnetic bearings
- F16C32/044—Active magnetic bearings
- F16C32/0474—Active magnetic bearings for rotary movement
- F16C32/0489—Active magnetic bearings for rotary movement with active support of five degrees of freedom, e.g. two radial magnetic bearings combined with an axial bearing
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16C—SHAFTS; FLEXIBLE SHAFTS; ELEMENTS OR CRANKSHAFT MECHANISMS; ROTARY BODIES OTHER THAN GEARING ELEMENTS; BEARINGS
- F16C32/00—Bearings not otherwise provided for
- F16C32/04—Bearings not otherwise provided for using magnetic or electric supporting means
- F16C32/0406—Magnetic bearings
- F16C32/044—Active magnetic bearings
- F16C32/0459—Details of the magnetic circuit
- F16C32/0461—Details of the magnetic circuit of stationary parts of the magnetic circuit
- F16C32/0465—Details of the magnetic circuit of stationary parts of the magnetic circuit with permanent magnets provided in the magnetic circuit of the electromagnets
Abstract
The invention relates to a low power consumption 5-DOF (Degree of Freedom) permanent magnet offset magnetic suspension bearing system belonging to a magnetic suspension bearing, which comprises a high-speed motor, a low power consumption permanent magnet offset axial and radial magnetic baring and a low power consumption permanent magnet offset radial magnetic bearing. 5-DOF (Degree of Freedom) suspension utilizes two radial magnetizing annular permanent magnetic bodies to establish a static offset magnetic field and runs through a 3-DOF (Degree of Freedom) magnetic bearing radial magnetic pole, a radial air gap, a rotor iron core, a rotor and a 2-DOF (Degree of Freedom) permanent magnet offset magnetic bearing radial stator to form a closed magnetic circuit; an axial winding generates control magnetic flux and offset magnetic flux superposition to control axial suspension; a radial control winding of three magnetic poles on the left end and the right end generates the control magnetic flux and the offset magnetic flux suspension; a triple/binary conversion principle of an alternating current motor is used to realize radial 4-DOF (Degree of Freedom) suspension; the system has a simple structure, high critical speed of rotation and low power consumption and has wide application prospect in the fields of aerospace, automobiles and motorcycles, mould machining, textile, chemical engineering machinery, etc.
Description
Technical field
Low power consumption 5-freedom permanent magnetism off-set magnetic suspension bearing system of the present invention belongs to the suspension of five-freedom degree magnetic bearing that magnetic bearing technology and high-speed electric expreess locomotive combine.
Background technique
Modern industrial production and communications and transportation more and more be unable to do without at a high speed and the development of ultra high speed motor, have particularly obtained extensive use at field high-speed electric expreess locomotives such as Aeronautics and Astronautics, navigation, automobile and motorcycle industry, machining and productions.But the bearings technology is the obstacle that the restriction high-speed electric expreess locomotive is realized high-power practicability always.Current, angular contact ball bearing is because contact wear heating, and bearing capacity and rigidity are little, very easily mechanical failure takes place and stop work and production causes great economic loss even personnel's injures and deaths.Magnetic suspension bearing then is to utilize the magnetic force between stator and the rotor that rotor is suspended in the space, make a kind of novel high-performance bearing that does not have Mechanical Contact between stator and the rotor, owing to there is not contact mechanically between the stator and rotor, so the rotor of magnetic suspension bearing can reach very high running rotating speed, and have advantages such as mechanical wear is little, energy consumption is low, the life-span is long, unlubricated, pollution-free, be particularly suitable for special applications such as high speed, vacuum and super cleaning.
But just simple two radial magnetic bearings and the axial magnetic bearing of adopting of traditional high-speed electric expreess locomotive system replaces five degrees of freedom suspensions that mechanical bearing is controlled motor, occupies suitable axial space, complex structure, and reliability and Security are not high.Numerous in the world scholars have proposed the Three Degree Of Freedom permanent-magnetic biased axial/radial hybrid magnetic bearing of various ways since 2000, this class magnetic bearing has partly solved the low problem of magnetic bearing axial space availability ratio, but its design, installation are relatively complicated, especially higher to axial installation requirement.
Three, summary of the invention
The objective of the invention is to propose a kind of compact structure, volume is little, the permanent magnet biased magnetic bearing system that five degree of freedom easy for installation, low power consumption suspends.
A kind of low power consumption 5-freedom permanent magnetism off-set magnetic suspension bearing system, it is characterized in that, comprise a high-speed electric expreess locomotive, a low power consumption permanent magnet biased axial radial direction magnetic bearing and a low power consumption permanent magnet biased radial direction magnetic bearing, described low power consumption permanent magnet biased axial radial direction magnetic bearing is the Three Degree Of Freedom permanent magnetism off-set magnetic suspension bearing, comprise the Three Degree Of Freedom radial stator, Three Degree Of Freedom is radially controlled winding, axially control winding, the Three Degree Of Freedom rotor core, rotor, the Three Degree Of Freedom annular permanent magnet, wherein Three Degree Of Freedom is radially controlled on the radially-outer surface that winding is sleeved on the Three Degree Of Freedom radial stator, axially the control winding is that simplex winding is mounted on the axial internal surface of Three Degree Of Freedom radial stator, the Three Degree Of Freedom rotor core places in the inboard circle of Three Degree Of Freedom radial stator, the Three Degree Of Freedom rotor core is installed in the rotor left end accordingly, and the Three Degree Of Freedom annular permanent magnet is mounted on the outer circumference surface of Three Degree Of Freedom radial stator; Described low power consumption permanent magnet biased radial direction magnetic bearing is the two-freedom permanent magnetism off-set magnetic suspension bearing, with the shared rotor of described Three Degree Of Freedom permanent magnetism off-set magnetic suspension bearing, other also comprises the two-freedom radial stator, two-freedom is radially controlled winding, the two-freedom rotor core, the two-freedom annular permanent magnet, wherein two-freedom is radially controlled on the radially-outer surface that winding is sleeved on the two-freedom radial stator, the two-freedom rotor core places in the inboard circle of two-freedom radial stator, the two-freedom rotor core is installed in the rotor right-hand member accordingly, and the two-freedom annular permanent magnet is mounted on the outer circumference surface of two-freedom radial stator; Described high-speed electric expreess locomotive places between Three Degree Of Freedom permanent magnetism off-set magnetic suspension bearing and the two-freedom permanent magnetism off-set magnetic suspension bearing, wherein the high speed rotor of motor iron core is sleeved on the neutral position of rotor, described outer core places the outer periphery surface of high-speed electric expreess locomotive stator, and is mounted on simultaneously on the outer surface of the outer surface of Three Degree Of Freedom annular permanent magnet and two-freedom annular permanent magnet.Basic functional principle of the present invention is: an end Three Degree Of Freedom permanent magnet biased magnetic bearing, its radial stator is wideer than rotor core, the permanent magnet bias magnetic flux that the annular permanent-magnet body of radial magnetizing produces is through radial stator, radial air gap arrival rotor core the time, produced biasing magnetic flux with axial component, when rotor is positioned at the longitudinal balance position, because the symmetry properties of structure, the magnetic flux at the right side of rotor core axial end air gap and left side air gap place equate that this moment, left and right sides suction equated.If rotor is subjected to the outer power of disturbing left at this moment, rotor will depart from the equilibrium position to left movement, the flux change about causing that the annular permanent-magnet body produces, and promptly the air gap on the right side increases, and magnetic flux reduces, and promptly the axial magnetic flux component reduces; The air gap on the left side reduces, and magnetic flux increases, and promptly the axial magnetic flux component increases.Because square being directly proportional of magnetic field suction and magnetic flux, therefore the suction on the right is less than the suction on the left side, add control magnetic flux before, rotor can't be got back to the equilibrium position.This moment, displacement transducer detected the displacement amount that rotor departs from its reference position, controller is transformed into control signal with this displacement signal, power amplifier is transformed into the control electric current with this control signal again, this electric current is flowed through and is mounted on axial control winding under the radial stator, in air gap, produce an electromagnetism magnetic flux, permanent magnet flux axial component stack in this electromagnetism magnetic flux and the air gap, magnetic flux in the air gap of the rotor right side is increased, magnetic flux in the air gap of the left side reduces, produce a suction to the right, rotor is retracted the equilibrium position.In like manner, rotor is subjected to axial outer disturbance left, can make rotor be returned to the equilibrium position equally based on above-mentioned principle.The working principle of four-degree-of-freedom axial magnetic (is example with the Vertical direction) is: be wound with i.e. three phase windings radially of three-phase control winding on the radial stator iron core, adopt three-phase inverter that the control electric current is provided, when being subjected to a downward disturbing force, rotor departs from the equilibrium position, displacement transducer detects the displacement amount that rotor departs from its reference position, controller is transformed into control signal with this displacement signal, three-phase inverter is transformed into the control electric current with this control signal again, in the three-phase electromagnetic coil, produce the biasing magnetic flux stack in control magnetic flux and the radial air gap, three/two principle of coordinate transformation based on AC motor produce synthetic unipolar flux upwards, make rotor be returned to the equilibrium position.In like manner, no matter rotor is subjected to upwards, to the right or disturbing force left, and the degenerative permanent-magnetic biased axial radial magnetic bearing in band position is by the electric current in the controller control exciting winding, and the size of regulating air-gap flux can keep rotor in the equilibrium position all the time.In like manner, the two-freedom permanent magnet offset radial magnetic bearing radial suspension mechanism of the other end is same as described above, has realized the radial suspension of rotor four-degree-of-freedom.
Low power consumption 5-freedom permanent magnetism off-set magnetic suspension bearing system of the present invention, high-speed electric expreess locomotive and permanent magnet biased magnetic bearing technology are organically combined, it utilizes the annular permanent-magnet body of two radial magnetizings to set up quiescent biasing magnetic field, pass through outer core, rotor core, rotor and radial stator form closed magnetic circuit, the radial stator magnetic pole that only needs two three magnetic poles, one mounts axial control winding under the at one end wide radial stator and six and radially controls winding, with respect to traditional five degree of freedom magnetic bearing system, reduced by two axial stator iron cores, axially control winding for one, two radial stator magnetic poles and two radially control winding, greatly simplify the structure, dwindled volume and weight, reduced by two magnetic bearing switch power amplifiers, reduced the bearing power consumption, reduced the axial installation difficulty of system, and has short axial space, at automobile/motorcycle industry, Mould Machining, high speed applications such as weaving and chemical machinery have broad application prospects, and national defence fields such as Aero-Space and naval vessels that it is used in then have more significance.
Four, description of drawings
Fig. 1 is a low power consumption 5-freedom magnetic levitation bearing system structural plan schematic representation.
Label title among Fig. 1: 1, Three Degree Of Freedom radial stator, 2, Three Degree Of Freedom radially controls winding, 3, axially control winding, 4, Three Degree Of Freedom rotor core, 5, rotor, 6, the high speed rotor of motor iron core, 7, the high-speed electric expreess locomotive stator, 8, Three Degree Of Freedom annular permanent magnet, 9, outer core, 10, the two-freedom radial stator, 11, two-freedom radially controls winding, 12, two-freedom annular permanent magnet, 4 ', the two-freedom rotor core.
Fig. 2 is low power consumption 5-freedom magnetic levitation bearing system five degree of freedom suspension theory figure.
Label title among Fig. 2: solid line is represented the permanent magnet bias magnetic flux, and single dotted line represents radially to control the control magnetic flux that winding produces, and doublet represents axially to control the control magnetic flux that winding produces.
Five, embodiment
Fig. 1 is a suspension of five-freedom degree magnetic bearing arrangement structural representation of the present invention, and it mainly is made up of high-speed electric expreess locomotive, Three Degree Of Freedom permanent magnet biased magnetic bearing and two-freedom permanent magnet biased hybrid magnetic bearing.Three Degree Of Freedom radial stator magnetic pole 1 among Fig. 1 is made for silicon steel plate stacking, be three field structures, Three Degree Of Freedom annular permanent magnet 8 is mounted on the position of the outside of Three Degree Of Freedom radial stator 1, on three magnetic pole of the stator, be with Three Degree Of Freedom and radially control winding 2, but this stator is wideer than rotor core 4, have the biasing magnetic flux of axial component in order to generation, axially control the internal surface that winding 3 is mounted on Three Degree Of Freedom radial stator 1.Two-freedom radial stator 10 is three field structures also for silicon steel plate stacking forms, and two-freedom annular permanent magnet 12 is mounted on the position of the outside of two-freedom radial stator 10, is with two-freedom and radially controls winding 11 on three magnetic pole of the stator.In order to reduce influence to high-speed electric expreess locomotive, install one additional in order to the outer core 9 of stream with the biasing magnetic flux, to make with electrical pure iron, its interior edge face links to each other with 12 outer ends with two annular permanent-magnet bodies 8, places the outside of motor stator 7.Magnetic circuit figure is shown in the schematic diagram of Fig. 2.The biasing magnetic flux that the annular permanent-magnet body produces constitutes the loop through Three Degree Of Freedom permanent magnet biased magnetic bearing magnet radial poles, radial air gap, rotor core, rotor, the rotor core of two-freedom permanent magnet biased magnetic bearing, radial air gap and two-freedom permanent magnet biased magnetic bearing radial stator successively, shown in the solid line among Fig. 2.Axially the control magnetic flux of control winding generation is through radial stator and axial air-gap, shown in the doublet among Fig. 2.The control magnetic flux of radially controlling the winding generation only passes through radial air gap and radial stator, without axial air-gap, shown in the single dotted line among Fig. 2.Axially control magnetic flux and radially control magnetic flux decoupling zero each other, do not disturb mutually.
Claims (1)
1, a kind of low power consumption 5-freedom permanent magnetism off-set magnetic suspension bearing system, it is characterized in that, comprise a high-speed electric expreess locomotive, a low power consumption permanent magnet biased axial radial direction magnetic bearing and a low power consumption permanent magnet biased radial direction magnetic bearing, described low power consumption permanent magnet biased axial radial direction magnetic bearing is the Three Degree Of Freedom permanent magnetism off-set magnetic suspension bearing, comprise Three Degree Of Freedom radial stator (1), Three Degree Of Freedom is radially controlled winding (2), axially control winding (3), Three Degree Of Freedom rotor core (4), rotor (5), Three Degree Of Freedom annular permanent magnet (8), wherein Three Degree Of Freedom is radially controlled winding (2) and is sleeved on the radially-outer surface of Three Degree Of Freedom radial stator (1), axially control winding (3) is mounted on the axial internal surface of Three Degree Of Freedom radial stator (1) for simplex winding, Three Degree Of Freedom rotor core (4) places in the inboard circle of Three Degree Of Freedom radial stator (1), Three Degree Of Freedom rotor core (4) is installed in rotor (5) left end accordingly, and Three Degree Of Freedom annular permanent magnet (8) is mounted on the outer circumference surface of Three Degree Of Freedom radial stator (1); Described low power consumption permanent magnet biased radial direction magnetic bearing is the two-freedom permanent magnetism off-set magnetic suspension bearing, with the shared rotor of described Three Degree Of Freedom permanent magnetism off-set magnetic suspension bearing (5), other also comprises two-freedom radial stator (10), two-freedom is radially controlled winding (11), two-freedom rotor core (4 '), two-freedom annular permanent magnet (12), wherein two-freedom is radially controlled winding (11) and is sleeved on the radially-outer surface of two-freedom radial stator (10), two-freedom rotor core (4 ') places in the inboard circle of two-freedom radial stator (10), two-freedom rotor core (4 ') is installed in rotor (5) right-hand member accordingly, and two-freedom annular permanent magnet (12) is mounted on the outer circumference surface of two-freedom radial stator (10); Described high-speed electric expreess locomotive places between Three Degree Of Freedom permanent magnetism off-set magnetic suspension bearing and the two-freedom permanent magnetism off-set magnetic suspension bearing, wherein high speed rotor of motor iron core (6) is sleeved on the neutral position of rotor (5), described outer core (9) places the outer periphery surface of high-speed electric expreess locomotive stator (7), and is mounted on simultaneously on the outer surface of the outer surface of Three Degree Of Freedom annular permanent magnet (8) and two-freedom annular permanent magnet (12).
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CNB2008100198144A CN100545474C (en) | 2008-03-17 | 2008-03-17 | Low power consumption 5-freedom permanent magnetism off-set magnetic suspension bearing system |
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CNB2008100198144A CN100545474C (en) | 2008-03-17 | 2008-03-17 | Low power consumption 5-freedom permanent magnetism off-set magnetic suspension bearing system |
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CN101806323A (en) * | 2010-04-29 | 2010-08-18 | 苏州同心医疗器械有限公司 | Five degree-of-freedom permanent magnet biased magnetic bearing |
CN101832335A (en) * | 2010-05-25 | 2010-09-15 | 南京化工职业技术学院 | Permanent magnet biased axial-radial magnetic bearing |
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CN101806323A (en) * | 2010-04-29 | 2010-08-18 | 苏州同心医疗器械有限公司 | Five degree-of-freedom permanent magnet biased magnetic bearing |
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CN103038541B (en) * | 2010-06-08 | 2016-04-27 | 时间功率有限公司 | Flywheel energy system |
CN101973218A (en) * | 2010-10-20 | 2011-02-16 | 哈尔滨工业大学 | Magnetic suspension linear guide rail with differential-type serial magnetic circuit structure |
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CN108591258A (en) * | 2018-05-10 | 2018-09-28 | 中国科学院国家天文台南京天文光学技术研究所 | Horizon open frame for Large-Scale Precision Instrument and Equipment |
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