CN112727921B - Super-stable super-static single-shaft rotary table supported by active magnetic suspension bearing - Google Patents

Abstract

The invention discloses an ultrastable and ultrastatic uniaxial rotary table supported by an active magnetic suspension bearing, wherein a plurality of radial and axial magnetic bearing integrated rotor assemblies (2) with the same structure are arranged on the circumference of a disc body (3), four radial and axial magnetic bearing integrated stator assemblies (6, 7, 8 and 9) are symmetrically distributed on the outer circumference of a magnetic suspension rotating platform (1), and a uniaxial rotary table driving mechanism (5) is arranged at the center of the magnetic suspension rotating platform (1). Under the condition of electrification, the radial and axial magnetic bearing integrated stator components (6, 7, 8 and 9) are firstly electrified to enable the radial and axial magnetic bearing integrated rotor component (2) to be suspended, and then the radial and axial magnetic bearing integrated rotor component (2) is rotated by the single-shaft turntable driving mechanism (5), so that complete suspension rotation is realized.

Description

Super-stable super-static single-shaft rotary table supported by active magnetic suspension bearing

Technical Field

The invention relates to a turntable suitable for magnetic suspension, in particular to an ultra-stable and ultra-static single-shaft turntable capable of realizing five-degree-of-freedom active magnetic suspension bearing support.

Background

In recent years, with the progress of magnetic suspension technology, high-speed magnetic suspension motors are rapidly developed, have the advantages of high rotating speed, high power density, small volume, quick response, capability of directly driving loads and the like, and are widely applied to high-speed rotating equipment such as high-speed magnetic suspension blowers, magnetic suspension ultrahigh vacuum molecular pumps, magnetic suspension energy storage flywheels, magnetic suspension moment gyros and the like. The load-bearing capacity of a magnetic bearing is determined by design and is limited by the size of the dimensions, and if the actual load exceeds this load-bearing capacity, or if the bearing of the magnetic bearing fails for some reason, the rotor will no longer be in suspension and will touch the mechanical boundary. In order to avoid damage to the lamination on the rotor and the magnetic bearing stator in this drop impact, protective bearings are installed. The protective bearings serve to temporarily support the rotor and protect the stator system.

The magnetic levitation technology is specifically a magnetic levitation bearing (or called magnetic bearing) technology, and uses electromagnetic force to suspend a rotor so as to replace the traditional mechanical bearing support. The magnetic bearing can overcome the defect of large friction loss of the mechanical bearing, the rotor does not have any mechanical contact, friction and lubrication in the operation process, and the mechanical service life is prolonged. The rotation speed can therefore be very high, typically between 10000rpm and 60000 rpm. The geometric dimension of the device is far smaller than that of the conventional rotating equipment with the same output power, so that the material is effectively saved, and the energy density of the equipment is greatly improved. The magnetic suspension technology makes it possible to drive the load directly without speed increasing mechanism, and this can reduce the system volume, realize zero transmission loss operation, raise efficiency and lower operation noise greatly.

Disclosure of Invention

The invention aims to solve the vibration problem of a mechanical turntable used in the field of precision measurement. The invention adopts the active vibration suppression function of the magnetic suspension bearing to realize mechanical isolation on the micro-vibration of the rotary table, thereby achieving the purpose of ultra-stability and ultra-statics. Because the magnetic suspension bearing has the characteristics of no friction and no need of lubrication, the adopted driving motor can directly drive the rotary table to rotate precisely, the mechanical vibration caused by the transmission of the speed reducer is avoided, and the complete vibration isolation of the driving and the supporting is realized. The invention can realize the physical isolation of vibration mechanically, cut off the propagation path of the vibration source congenital, avoid the interference of the rotary table to the precision measurement part, can greatly improve the precision measurement grade of the rotary table, and realize the theoretical and technical breakthrough of the basic subject.

The invention relates to an ultrastable and ultrastable uniaxial rotary table supported by an active magnetic suspension bearing, wherein a plurality of radial and axial magnetic bearing integrated rotor assemblies (2) with the same structure are arranged on the circumference of a disc body (3), four radial and axial magnetic bearing integrated stator assemblies (6, 7, 8 and 9) are symmetrically distributed on the outer circumference of a magnetic suspension rotating platform (1), and a uniaxial rotary table driving mechanism (5) is arranged at the center of the magnetic suspension rotating platform (1). Under the condition of electrification, the radial and axial magnetic bearing integrated stator components (6, 7, 8 and 9) are firstly electrified to enable the radial and axial magnetic bearing integrated rotor component (2) to be suspended, and then the radial and axial magnetic bearing integrated rotor component (2) is rotated by the single-shaft turntable driving mechanism (5), so that complete suspension rotation is realized.

On one hand, the single-shaft turntable driving mechanism (5) adopts the magnetic suspension bearing, has the characteristics of no friction and no lubrication, and avoids mechanical vibration caused by the transmission of a speed reducer, so the driving mechanism is called super-stable and super-static. On the other hand, the designed four radial and axial magnetic bearing integrated stator components (6, 7, 8 and 9) adopt the magnetic suspension technology, and can also achieve the hyperstatic effect.

The invention discloses an ultrastable and ultrastable uniaxial rotary table supported by an active magnetic suspension bearing, which comprises an A-radial and axial magnetic bearing integrated stator assembly (6), a B-radial and axial magnetic bearing integrated stator assembly (7), a C-radial and axial magnetic bearing integrated stator assembly (8), a D-radial and axial magnetic bearing integrated stator assembly (9), a radial and axial magnetic bearing integrated rotor assembly (2), a disc body (3), a base (4) and a uniaxial rotary table driving mechanism (5); the disk body (3) and a plurality of radial-axial magnetic bearing integrated rotor assemblies (2) distributed along the circumference of the disk body (3) form a magnetic suspension rotating platform (1);

the radial and axial magnetic bearing integrated rotor assembly (2) is composed of a rotor bracket (2A), a rotor lamination (2B), a rotor upper pressing plate (2C) and a rotor lower pressing plate (2);

a BA support arm (2A1) and a BB support arm (2A2) are arranged on one side of the rotor support (2A), and a BA groove (2A3) is formed between the BA support arm (2A1) and the BB support arm (2A 2); the other side of the rotor bracket (2A) is provided with a BC support arm (2A4) and a BD support arm (2A5), and a BB groove (2A6) is arranged between the BC support arm (2A4) and the BD support arm (2A 5); the BA groove (2A3) is used for placing an outer edge surface (3B) of the disc body (3), and the BA support arm (2A1) and the BB support arm (2A2) are fixed on the disc body (3) through screws; the BB groove (2A6) is used for placing a rotor lamination (2B); a rotor upper pressure plate (2C) is fixed on the BC support arm (2A4) by a screw; a rotor lower pressing plate (2D) is fixed on the BD supporting arm (2A5) through a screw;

a plurality of radial-axial magnetic bearing integrated rotor assemblies (2) are distributed along the circumference of the disc body (3);

the disc body (3) is of a flat circular disc structure, a central through hole (3A) is formed in the center of the disc body (3), and the central through hole (3A) is used for allowing one end of a fifth rotating shaft (5A) of the single-shaft rotary table driving mechanism (5) to penetrate through; the edge of the disc body (3) is an outer edge surface (3B), and a plurality of radial and axial magnetic bearing integrated rotor assemblies (2) which are distributed circumferentially are mounted on the outer edge surface (3B);

the disk body (3) and a magnetic suspension rotating platform (1) formed by a plurality of radial and axial magnetic bearing integrated rotor assemblies (2) distributed along the circumference of the disk body (3); the magnetic suspension rotating platform (1) is driven by a turntable driving motor assembly (5) to rotate;

a DA through hole (4A) is formed in the center of the base (4), a DA boss (4B) is arranged above the DA through hole (4A), a DB boss (4E) is arranged below the DA through hole (4A), and a DC boss (4F) is arranged in the DA through hole (4A); a countersunk head cavity (4C) and an outer boss (4D) are arranged above the base (4), and four magnetic suspension bearing stator assemblies, namely an A radial axial magnetic bearing integrated stator assembly (6), a B radial axial magnetic bearing integrated stator assembly (7), a C radial axial magnetic bearing integrated stator assembly (8) and a D radial axial magnetic bearing integrated stator assembly (9), are uniformly distributed on the outer boss (4D); be equipped with the blind hole on the outer fringe face (4H) of base (4) of installing magnetic suspension bearing stator module department, promptly:

DA blind holes are formed in the outer edge surface (4H) of the base (4) at the position of the integrated stator assembly (6) of the A-diameter axial magnetic bearing; the DA blind hole is used for mounting one end of a first rotating shaft (10A) of the first driving mechanism (10);

a DB blind hole (4G2) is arranged on the outer edge surface (4H) of the base (4) at the position of the integrated stator component (7) of the radial-axial magnetic bearing B; the DB blind hole (4G2) is used for mounting one end of a third rotating shaft (12A) of a third driving mechanism (12);

a DC blind hole (4G3) is arranged on the outer edge surface (4H) of the base (4) at the position of the integrated stator component (8) of the C-diameter axial magnetic bearing; the DC blind hole (4G3) is used for mounting one end of a second rotating shaft (11A) of the second driving mechanism (11);

a DD blind hole is arranged on the outer edge surface (4H) of the base (4) at the position of the integrated stator component (9) of the D-diameter axial magnetic bearing; the DD blind hole is used for mounting one end of a fourth rotating shaft (13A) of a fourth driving mechanism (13);

the base (4) is arranged below the disc body (3);

the single-shaft turntable driving mechanism (5) comprises a rotating shaft (5A), a motor stator (5B), an EA coil (5C), a rotor baffle ring (5E), a sheath (5F) and a permanent magnet (5G);

the rotating shaft (5A) is provided with an EA shaft section (5A1), an EB shaft section (5A2), an EC shaft section (5A3) and a shaft shoulder (5A 4); a shaft shoulder (5A4) is arranged between the EA shaft section (5A1) and the EB shaft section (5A 2);

the EA shaft section (5A1) is used for passing through the central through hole (3A) of the disc body (3) and is fixedly installed with the disc body (3);

the upper end of the EA coil (5C) is placed on the EB shaft section (5A 2);

the EC shaft section (5A3) is sleeved with a permanent magnet (5G), the outer part of the permanent magnet (5G) is sleeved with a sheath (5F), the upper ends of the permanent magnet (5G) and the sheath (5F) are tightly propped against the lower end face of the EB shaft section (5A2), and the lower ends of the permanent magnet (5G) and the sheath (5F) are provided with a rotor baffle ring (5E); a motor stator (5B) is sleeved outside the sheath (5F);

coil frameworks (5D) are uniformly distributed on the inner circumference of the motor stator (5B), coil grooves (5D1) are formed between every two adjacent coil frameworks (5D), and coils (5C) are placed in the coil grooves (5D 1);

the motor stator (5B) is fixedly arranged in the DA through hole (4A) of the base (4);

the A-diameter axial magnetic bearing integrated stator component (6) comprises an FA magnetic bearing support (6A), an FB magnetic bearing support (6B), an FA radial probe support (6C), an FB radial probe support (6D), an A-radial magnetic bearing stator coil (6E), an A-radial magnetic bearing stator (6F), an FA axial magnetic bearing stator (6G), an FB axial magnetic bearing stator (6H), an FA axial magnetic bearing stator coil (6I), an FB axial magnetic bearing stator coil (6J), an FA axial probe (6K), an FB axial probe (6L), an FC axial probe (6M), an FD axial probe (6N), an FA radial probe (6O) and an FB radial probe (6P);

the FA bearing support (6A) and the FB bearing support (6B) have the same structure; an FA supporting arm (6A1) and an FB supporting arm (6A2) are arranged on the FA bearing support (6A); the FB support arm (6A2) is fixed on the upper end plate surface (6C1) of the FA radial probe bracket (6C); the FB bearing support (6B) is provided with an FC support arm (6B1) and an FD support arm (6B 2); the FD support arm (6B2) is fixed on the lower end plate surface of the FB radial probe bracket (6D);

the FA radial probe bracket (6C) and the FB radial probe bracket (6D) have the same structure; an FA through hole (6C4) and an FA opening groove (6C3) are formed in a side plate surface (6C2) of the FA radial probe bracket (6C); the upper end plate surface (6C1) of the FA radial probe bracket (6C) is fixed with an FB support arm (6A2) of the FA bearing bracket (6A); the lower end plate surface of the FA radial probe bracket (6C) is fixed with the upper end plate surface (6D1) of the FB radial probe bracket (6D); the FA through hole (6C4) is used for mounting the FB radial probe (6P); an FB through hole (6D4) and an FB opening groove (6D3) are formed in a side plate surface (6D2) of the FB radial probe support (6D); the lower end plate surface of the FB radial probe bracket (6D) is fixed with an FD support arm (6B2) of the FB bearing bracket (6B); the FB through hole (6D4) is used for mounting the FA radial probe (6O); the FA open groove (6C3) and the FB open groove (6D3) are formed into a rectangular groove in a conformal mode, the rectangular groove is used for fixing an A radial magnetic bearing stator (6F), and an A radial magnetic bearing stator coil (6E) is wound on the A radial magnetic bearing stator (6F);

the FA axial magnetic bearing stator (6G) and the FB axial magnetic bearing stator (6H) have the same structure; the left end and the right end of the FA axial magnetic bearing stator (6G) are respectively provided with an FC through hole (6G1) and an FD through hole (6G 2); one plate surface of the FA axial magnetic bearing stator (6G) is a flat plate surface; the other plate surface of the FA axial magnetic bearing stator (6G) is provided with an FA axial magnetic coil framework (6G3) and an FA axial magnetic coil groove (6G 4); the FC through hole (6G1) is used for mounting the FB axial probe (6L); the FD through hole (6G2) is used for installing an FA axial probe (6K); an FA axial magnetic bearing stator coil (6I) is wound on the FA axial magnetic coil framework (6G3), and the FA axial magnetic bearing stator coil (6I) is arranged in the FA axial magnetic coil groove (6G 4); the left end and the right end of the FB axial magnetic bearing stator (6H) are respectively provided with an FE through hole (6H1) and an FF through hole (6H 2); one plate surface of the FB axial magnetic bearing stator (6H) is a flat plate surface; the other plate surface of the FB axial magnetic bearing stator (6H) is provided with an FB shaft magnetic coil framework (6H3) and an FB shaft magnetic coil groove (6H 4); the FE through hole (6H1) is used for installing the FD axial probe 6N; the FF through hole (6H2) is used for installing an FC axial probe (6M); an FB axial magnetic bearing stator coil (6J) is wound on the FB axial magnetic coil framework (6H3), and the FB axial magnetic bearing stator coil (6J) is arranged in the FB axial magnetic coil groove (6H 4);

the B-radial-axial magnetic bearing integrated stator assembly (7) comprises a GA bearing support (7A), a GB bearing support (7B), a GA radial probe support (7C), a GB radial probe support (7D), a B-radial magnetic bearing stator coil (7E), a B-radial magnetic bearing stator (7F), a GA axial magnetic bearing stator (7G), a GB axial magnetic bearing stator (7H), a GA axial magnetic bearing stator coil (7I), a GB axial magnetic bearing stator coil (7J), a GA axial probe (7K), a GB axial probe (7L), a GC axial probe (7M), a GD axial probe (7N), a GA radial probe (7O) and a GB radial probe (7P);

the GA bearing support (7A) and the GB bearing support (7B) have the same structure; a GA support arm (7A1) and a GB support arm (7A2) are arranged on the GA bearing support (7A); the GB support arm (7A2) is fixed on the upper end plate surface (7C1) of the GA radial probe bracket (7C); a GC support arm (7B1) and a GD support arm (7B2) are arranged on the GB bearing support (7B); the GD support arm (7B2) is fixed on the lower end plate surface of the GB radial probe bracket (7D);

the GA radial probe bracket (7C) and the GB radial probe bracket (7D) have the same structure; a GA through hole (7C4) and a GA opening groove (7C3) are formed in the side plate surface (7C2) of the GA radial probe bracket (7C); the upper end plate surface (7C1) of the GA radial probe bracket (7C) is fixed with a GB support arm (7A2) of the GA bearing bracket (7A); the lower end plate surface of the GA radial probe bracket (7C) is fixed with the upper end plate surface (7D1) of the GB radial probe bracket (7D); the GA through hole (7C4) is used for mounting a GB radial probe (7P); a GB through hole (7D4) and a GB opening groove (7D3) are formed in a side plate surface (7D2) of the GB radial probe bracket (7D); the lower end plate surface of the GB radial probe bracket (7D) is fixed with a GD support arm (7B2) of the GB bearing bracket (7B); the GB through hole (7D4) is used for installing the GA radial probe (7O); the GA open groove (7C3) and the GB open groove (7D3) are formed into a rectangular groove in a conformal mode, the rectangular groove is used for fixing a B radial magnetic bearing stator (7F), and the B radial magnetic bearing stator coil (7E) is wound on the B radial magnetic bearing stator (7F);

the structure of the GA axial magnetic bearing stator (7G) is the same as that of the GB axial magnetic bearing stator (7H); the left end and the right end of the GA axial magnetic bearing stator (7G) are respectively provided with a GC through hole (7G1) and a GD through hole (7G 2); one plate surface of the GA axial magnetic bearing stator (7G) is a flat plate surface; the other plate surface of the GA axial magnetic bearing stator (7G) is provided with a GA shaft magnetic coil framework (7G3) and a GA shaft magnetic coil groove (7G 4); the GC through hole (7G1) is used for mounting a GB axial probe (7L); the GD through hole (7G2) is used for mounting a GA axial probe (7K); a GA axial magnetic bearing stator coil (7I) is wound on the GA axial magnetic coil framework (7G3), and the GA axial magnetic bearing stator coil (7I) is arranged in the GA axial magnetic coil groove (7G 4); the left end and the right end of the GB axial magnetic bearing stator (7H) are respectively provided with a GE through hole (7H1) and a GF through hole (7H 2); one plate surface of the GB axial magnetic bearing stator (7H) is a flat plate surface; the other plate surface of the GB axial magnetic bearing stator (7H) is provided with a GB shaft magnetic coil framework (7H3) and a GB shaft magnetic coil groove (7H 4); the GE through hole (7H1) is used for installing a GD axial probe (7N); the GF through hole (7H2) is used for installing a GC axial probe (7M); a GB axial magnetic bearing stator coil (7J) is wound on the GB axial magnetic coil framework (7H3), and the GB axial magnetic bearing stator coil (7J) is arranged in the GB axial magnetic coil groove (7H 4);

the C-diameter axial magnetic bearing integrated stator component (8) comprises an HA bearing support (8A), an HB bearing support (8B), an HA radial probe support (8C), an HB radial probe support (8D), a C radial magnetic bearing stator coil (8E), a C radial magnetic bearing stator (8F), an HA axial magnetic bearing stator (8G), an HB axial magnetic bearing stator (8H), an HA axial magnetic bearing stator coil (8I), an HB axial magnetic bearing stator coil (8J), an HA axial probe (8K), an HB axial probe (8L), an HC axial probe (8M), an HD axial probe (8N), an HA radial probe (8O) and an HB radial probe (8P);

the HA bearing support (8A) and the HB bearing support (8B) have the same structure; an HA support arm (8A1) and an HB support arm (8A2) are arranged on the HA bearing support (8A); the HB support arm (8A2) is fixed on the upper end plate surface (8C1) of the HA radial probe bracket (8C); an HC support arm (8B1) and an HD support arm (8B2) are arranged on the HB bearing support (8B); the HD support arm (8B2) is fixed on the lower end plate surface of the HB radial probe support (8D);

the HA radial probe bracket (8C) and the HB radial probe bracket (8D) have the same structure; an HA through hole (8C4) and an HA opening groove (8C3) are formed in a side plate surface (8C2) of the HA radial probe support (8C); an upper end plate surface (8C1) of the HA radial probe bracket (8C) is fixed with an HB support arm (8A2) of the HA bearing bracket (8A); the lower end plate surface of the HA radial probe bracket 8C is fixed with the upper end plate surface 8D1 of the HB radial probe bracket 8D; the HA through hole (8C4) is used for installing an HB radial probe (8P); an HB through hole (8D4) and an HB opening groove (8D3) are formed in the side plate surface (8D2) of the HB radial probe support (8D); the lower end plate surface of the HB radial probe support (8D) is fixed with an HD support arm (8B2) of the HB bearing support (8B); the HB through hole (8D4) is used for mounting an HA radial probe (8O); the HA open groove (8C3) and the HB open groove (8D3) are formed into a rectangular groove in a conformal manner, the rectangular groove is used for fixing a C radial magnetic bearing stator (8F), and a C radial magnetic bearing stator coil (8E) is wound on the C radial magnetic bearing stator (8F);

the HA axial magnetic bearing stator (8G) and the HB axial magnetic bearing stator (8H) have the same structure; the left end and the right end of the HA axial magnetic bearing stator (8G) are respectively provided with an HC through hole (8G1) and an HD through hole (8G 2); one plate surface of the HA axial magnetic bearing stator (8G) is a flat plate surface; the other plate surface of the HA axial magnetic bearing stator (8G) is provided with an HA axial magnetic coil framework (8G3) and an HA axial magnetic coil groove (8G 4); the HC through hole (8G1) is used for installing an HB axial probe (8L); the HD through hole (8G2) is used for mounting an HA axial probe (8K); an HA axial magnetic bearing stator coil (8I) is wound on the HA axial magnetic coil framework (8G3), and the HA axial magnetic bearing stator coil (8I) is arranged in the HA axial magnetic coil groove (8G 4); the left end and the right end of the HB axial magnetic bearing stator (8H) are respectively provided with an HE through hole (8H1) and an HF through hole (8H 2); one plate surface of the HB axial magnetic bearing stator (8H) is a flat plate surface; the other plate surface of the HB axial magnetic bearing stator (8H) is provided with an HB axial magnetic coil framework (8H3) and an HB axial magnetic coil groove (8H 4); the HE through hole (8H1) is used for mounting an HD axial probe (8N); the HF through hole (8H2) is used for mounting an HC axial probe (8M); an HB axial magnetic bearing stator coil (8J) is wound on the HB axial magnetic coil framework (8H3), and the HB axial magnetic bearing stator coil (8J) is arranged in the HB axial magnetic coil groove (8H 4);

the D-diameter axial magnetic bearing integrated stator component (9) comprises an IA bearing support (9A), an IB bearing support (9B), an IA radial probe support (9C), an IB radial probe support (9D), a D-diameter axial magnetic bearing stator coil (9E), a D-diameter axial magnetic bearing stator (9F), an IA axial magnetic bearing stator (9G), an IB axial magnetic bearing stator (9H), an IA axial magnetic bearing stator coil (9I), an IB axial magnetic bearing stator coil (9J), an IA axial probe (9K), an IB axial probe (9L), an IC axial probe (9M), an ID axial probe (9N), an IA radial probe (9O) and an IB radial probe (9P);

the IA bearing support (9A) and the IB bearing support (9B) have the same structure; an IA support arm (9A1) and an IB support arm (9A2) are arranged on the IA bearing support (9A); the IB supporting arm (9A2) is fixed on the upper end plate surface (9C1) of the IA radial probe bracket (9C); an IC arm (9B1) and an ID arm (9B2) are arranged on the IB bearing support (9B); the ID support arm (9B2) is fixed on the lower end plate surface of the IB radial probe bracket (9D);

the IA radial probe bracket (9C) and the IB radial probe bracket (9D) have the same structure; an IA through hole (9C4) and an IA opening groove (9C3) are arranged on a side plate surface (9C2) of the IA radial probe bracket (9C); an upper end plate surface (9C1) of the IA radial probe bracket (9C) is fixed with an IB support arm (9A2) of the IA bearing bracket (9A); the lower end plate surface of the IA radial probe bracket (9C) is fixed with the upper end plate surface (9D1) of the IB radial probe bracket (9D); the IA through hole (9C4) is used for installing an IB radial probe (9P); an IB through hole (9D4) and an IB opening groove (9D3) are formed in a side plate surface (9D2) of the IB radial probe bracket (9D); the lower end plate surface of the IB radial probe bracket (9D) is fixed with an ID support arm (9B2) of the IB bearing bracket (9B); the IB through hole (9D4) is used for mounting the IA radial probe (9O); the IA open groove (9C3) and the IB open groove (9D3) are formed into a rectangular groove in a conformal mode, the rectangular groove is used for fixing a D radial magnetic bearing stator (9F), and the D radial magnetic bearing stator coil (9E) is wound on the D radial magnetic bearing stator (9F);

the IA axial magnetic bearing stator (9G) and the IB axial magnetic bearing stator (9H) have the same structure; the left end and the right end of the IA axial magnetic bearing stator (9G) are respectively provided with an IC through hole (9G1) and an ID through hole (9G 2); one plate surface of the IA axial magnetic bearing stator (9G) is a flat plate surface; the other plate surface of the IA axial magnetic bearing stator (9G) is provided with an IA shaft magnetic coil framework (9G3) and an IA shaft magnetic coil groove (9G 4); the IC through hole (9G1) is used for mounting the IB axial probe (9L); the ID through hole (9G2) is used for mounting the IA axial probe (9K); an IA axial magnetic bearing stator coil (9I) is wound on the IA axial magnetic coil framework (9G3), and the IA axial magnetic bearing stator coil (9I) is arranged in the IA axial magnetic coil groove (9G 4); IE through holes (9H1) and IF through holes (9H2) are respectively arranged at the left end and the right end of the IB axial magnetic bearing stator (9H); one plate surface of the IB axial magnetic bearing stator (9H) is a flat plate surface; the other plate surface of the IB axial magnetic bearing stator (9H) is provided with an IB shaft magnetic coil framework (9H3) and an IB shaft magnetic coil groove (9H 4); IE through hole (9H1) is used for installing ID axial probe (9N); the IF through hole (9H2) is used for mounting an IC axial probe (9M); an IB axial magnetic bearing stator coil (9J) is wound on the IB axial magnetic coil framework (9H3), and the IB axial magnetic bearing stator coil (9J) is arranged in the IB axial magnetic coil groove (9H 4).

The ultrastable hyperstatic uniaxial rotary table supported by the active magnetic suspension bearing has the advantages that:

the radial and axial magnetic bearing integrated stator component designed by the invention integrates the radial magnetic bearing stator and the axial magnetic bearing stator into a whole to form a module, has strong interchangeability and universality, and can be assembled and reconstructed in a modularized manner according to the bearing requirement.

Secondly, the radial and axial magnetic bearing integrated rotor component integrates the radial magnetic bearing rotor and the axial magnetic bearing rotor into a whole to form a module, so that the precise manufacturing of parts and parts can be realized, and further, the precise manufacturing of a rotary table can be realized.

The single-shaft turntable driving mechanism eliminates the transmission error of the reduction box and physically isolates the vibration transmission path from driving to loading.

The ultrastable superstable and superstatic single-shaft turntable is supported by the magnetic suspension bearing, is free of mechanical contact and lubrication, eliminates a propagation path of a vibration source, and can realize ultrastable and superstatic rotation.

Drawings

Fig. 1 is a structural diagram of an ultra-stable and ultra-static single-shaft turntable supported by an active magnetic suspension bearing of the invention.

Fig. 1A is another view structure diagram of the ultra-stable and ultra-static single-axis turntable supported by the active magnetic suspension bearing of the invention.

Fig. 1B is a cross-sectional view of the ultra-stable and ultra-static single-axis turntable supported by the active magnetic suspension bearing of the invention.

Fig. 2 is a structural view of the integrated rotor assembly for radial and axial magnetic bearings according to the present invention.

Fig. 2A is an exploded view of the integrated rotor assembly for radial and axial magnetic bearings in the present invention.

Fig. 3 is a structural view of the disk body in the present invention.

Fig. 3A is another perspective view of the disk body of the present invention.

Fig. 4 is a structural view of the base in the present invention.

Fig. 4A is another perspective view of the base of the present invention.

Fig. 5 is a structural view of a single-axis turntable driving mechanism in the present invention.

Fig. 5A is an exploded view of a single-axis turntable driving mechanism in the present invention.

Fig. 6 is a structural view of an a-diameter axial magnetic bearing integrated stator assembly in the present invention.

Fig. 6A is another perspective view structural view of the integrated stator assembly of the a-diameter axial magnetic bearing in the present invention.

Fig. 6B is an exploded view of an a-diameter axial magnetic bearing integral stator assembly of the present invention.

Fig. 6C is a structure view of the FA axial magnetic bearing stator of the a radial axial magnetic bearing integrated stator assembly according to the present invention.

Fig. 6D is a structure view of the FB axial magnetic bearing stator of the a radial axial magnetic bearing integrated stator assembly according to the present invention.

Fig. 7 is a structural view of a B-diameter axial magnetic bearing integrated stator assembly in the present invention.

Fig. 7A is another perspective view structural view of the B-diameter axial magnetic bearing integrated stator assembly in the present invention.

Fig. 7B is an exploded view of a B-diameter axial magnetic bearing integrated stator assembly of the present invention.

Fig. 7C is a structure view of the GA axial magnetic bearing stator of the B radial axial magnetic bearing integrated stator assembly of the present invention.

Fig. 7D is a GB axial magnetic bearing stator structure view of a B radial axial magnetic bearing integrated stator assembly in the present invention.

Fig. 8 is a structural view of a C-diameter axial magnetic bearing integrated stator assembly in the present invention.

Fig. 8A is another perspective view structural view of the integrated stator assembly of the C-diameter axial magnetic bearing in the present invention.

Fig. 8B is an exploded view of a unitary stator assembly of the C-diameter axial magnetic bearing of the present invention.

Fig. 8C is a view showing the structure of the HA axial magnetic bearing stator of the C radial axial magnetic bearing integrated stator assembly according to the present invention.

Fig. 8D is an HB axial magnetic bearing stator structure view of the C-diameter axial magnetic bearing integrated stator assembly in the present invention.

Fig. 9 is a structural view of a D-radial axial magnetic bearing integrated stator assembly in the present invention.

Fig. 9A is another perspective view structural view of the integrated stator assembly of the D-radial axial magnetic bearing in the present invention.

Fig. 9B is an exploded view of a one-piece stator assembly of the D-radial axial magnetic bearing of the present invention.

Fig. 9C is an IA axial magnetic bearing stator structure view of the D radial axial magnetic bearing integrated stator assembly of the present invention.

Fig. 9D is a view illustrating the construction of the IB axial magnetic bearing stator of the D radial axial magnetic bearing integrated stator assembly according to the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1, fig. 1A and fig. 1B, the ultrastable hyperstatic uniaxial rotary table supported by the active magnetic suspension bearing of the present invention comprises an a-radial axial magnetic bearing integrated stator assembly 6, a B-radial axial magnetic bearing integrated stator assembly 7, a C-radial axial magnetic bearing integrated stator assembly 8, a D-radial axial magnetic bearing integrated stator assembly 9, a radial axial magnetic bearing integrated rotor assembly 2, a disc body 3, a base 4 and a uniaxial rotary table driving mechanism 5; the disk body 3 and a plurality of radial and axial magnetic bearing integrated rotor assemblies 2 distributed along the circumference of the disk body 3 form a magnetic suspension rotating platform 1.

In the invention, in order to symmetrically arrange the A radial axial magnetic bearing integrated stator assembly 6, the B radial axial magnetic bearing integrated stator assembly 7, the C radial axial magnetic bearing integrated stator assembly 8 and the D radial axial magnetic bearing integrated stator assembly 9 which have the same structure along the magnetic suspension rotating platform 1, the A radial axial magnetic bearing integrated stator assembly 6, the B radial axial magnetic bearing integrated stator assembly 7, the C radial axial magnetic bearing integrated stator assembly 8 and the D radial axial magnetic bearing integrated stator assembly 9 are designed into an arc-shaped structure.

Radial-axial magnetic bearing integrated rotor assembly 2

Referring to fig. 2 and 2A, the radial and axial magnetic bearing integrated rotor assembly 2 is composed of a rotor support 2A, a rotor lamination 2B, a rotor upper pressure plate 2C and a rotor lower pressure plate 2.

A BA support arm 2A1 and a BB support arm 2A2 are arranged on one side of the rotor bracket 2A, and a BA groove 2A3 is arranged between the BA support arm 2A1 and the BB support arm 2A 2; the other side of the rotor bracket 2A is provided with a BC arm 2A4 and a BD arm 2A5, and a BB groove 2A6 is arranged between the BC arm 2A4 and the BD arm 2A 5. The BA recess 2A3 is used for placing the outer edge surface 3B of the disc body 3, and fixes the BA arm 2a1 and the BB arm 2a2 on the disc body 3 by screws. The BB groove 2a6 is used for placing the rotor stack 2B. A rotor upper pressure plate 2C is fixed to the BC boom 2a4 with screws. A rotor lower pressing plate 2D is fixed to the BD arm 2a5 by screws.

In the present invention, a plurality of radial and axial magnetic bearing integrated rotor assemblies 2 are distributed along the circumference of the disk body 3.

Disc body 3

Referring to fig. 3 and 3A, the circular disc body 3 is a flat circular disc structure, and a central through hole 3A is formed in the center of the circular disc body 3, and the central through hole 3A is used for one end of a fifth rotating shaft 5A of the single-shaft turntable driving mechanism 5 to pass through. The edge of the disk body 3 is an outer edge surface 3B, and a plurality of radial and axial magnetic bearing integrated rotor assemblies 2 distributed circumferentially are mounted on the outer edge surface 3B.

In the invention, a magnetic suspension rotating platform 1 is formed by a disc body 3 and a plurality of radial and axial magnetic bearing integrated rotor assemblies 2 distributed along the circumference of the disc body 3. The magnetic suspension rotating platform 1 is driven by a turntable driving motor assembly 5 to rotate.

Base 4

Referring to fig. 4 and 4A, a DA through hole 4A is formed in the center of the base 4, a DA boss 4B is arranged above the DA through hole 4A, a DB boss 4E is arranged below the DA through hole 4A, and a DC boss 4F is arranged in the DA through hole 4A; a countersunk cavity 4C and an outer boss 4D are arranged above the base 4, and four magnetic suspension bearing stator assemblies, namely an A radial axial magnetic bearing integrated stator assembly 6, a B radial axial magnetic bearing integrated stator assembly 7, a C radial axial magnetic bearing integrated stator assembly 8 and a D radial axial magnetic bearing integrated stator assembly 9, are uniformly distributed on the outer boss 4D. Four blind holes (namely, a DA blind hole, a DB blind hole 4G2, a DC blind hole 4G3 and a DD blind hole) are arranged on the outer edge surface 4H of the base 4 where the magnetic suspension bearing stator assembly is installed.

In the present invention, the base 4 is disposed below the disk body 3.

Single-shaft turntable driving mechanism 5

Referring to fig. 5 and 5A, the single-shaft turntable driving mechanism 5 includes a rotating shaft 5A, a motor stator 5B, EA coil 5C, a rotor retainer ring 5E, a sheath 5F, and a permanent magnet 5G.

The rotating shaft 5A is provided with an EA shaft section 5A1, an EB shaft section 5A2, an EC shaft section 5A3 and a shaft shoulder 5A 4; between EA shaft segment 5a1 and EB shaft segment 5a2 is shoulder 5a 4.

The EA shaft section 5a1 is inserted through the center through hole 3A of the disk body 3 and is fixedly attached to the disk body 3.

The EB shaft section 5a2 has an upper end for placing the EA coil 5C thereon.

The EC shaft section 5A3 is sleeved with a permanent magnet 5G, the outer part of the permanent magnet 5G is sleeved with a sheath 5F, the upper ends of the permanent magnet 5G and the sheath 5F are tightly propped against the lower end face of the EB shaft section 5A2, and the lower ends of the permanent magnet 5G and the sheath 5F are provided with a rotor baffle ring 5E; the motor stator 5B is sleeved outside the sheath 5F.

The inner circumference of the motor stator 5B is uniformly distributed with coil frameworks 5D, a coil groove 5D1 is arranged between the adjacent coil frameworks 5D, and a coil 5C is arranged in the coil groove 5D 1.

The motor stator 5B is fixedly installed in the DA through hole 4A of the base 4.

A-diameter axial magnetic bearing integrated stator assembly 6

Referring to fig. 6, 6A and 6B, the a-radial-axial magnetic bearing integrated stator assembly 6 includes a FA magnetic bearing support 6A, FB magnetic bearing support 6B, FA radial probe support 6C, FB radial probe support 6D, A radial magnetic bearing stator coil 6E, A radial magnetic bearing stator 6F, FA axial magnetic bearing stator 6G, FB axial magnetic bearing stator 6H, FA axial magnetic bearing stator coil 6I, FB axial magnetic bearing stator coil 6J, FA axial probe 6K, FB axial probe 6L, FC axial probe 6M, FD axial probe 6N, FA radial probe 6O and FB radial probe 6P.

Referring to fig. 6B, the FA bearing holder 6A is identical in structure to the FB bearing holder 6B. The FA bearing support 6A is provided with an FA support arm 6A1 and an FB support arm 6A 2. The FB arm 6A2 is fixed to the upper end plate 6C1 of the FA radial probe carrier 6C. The FB bearing support 6B is provided with an FC arm 6B1 and an FD arm 6B 2. The FD arm 6B2 is fixed to the lower end plate of the FB radial probe carrier 6D.

Referring to FIG. 6B, the FA radial probe holder 6C is identical in construction to the FB radial probe holder 6D. The side plate surface 6C2 of the FA radial probe bracket 6C is provided with an FA through hole 6C4 and an FA opening groove 6C 3. The upper end plate surface 6C1 of the FA radial probe bracket 6C is fixed with the FB support arm 6A2 of the FA bearing bracket 6A; the lower end plate surface of the FA radial probe holder 6C is fixed to the upper end plate surface 6D1 of the FB radial probe holder 6D. The FA through hole 6C4 is used to mount the FB radial probe 6P. The side plate surface 6D2 of the FB radial probe bracket 6D is provided with an FB through hole 6D4 and an FB opening groove 6D 3. The lower end plate surface of the FB radial probe bracket 6D is fixed to the FD arm 6B2 of the FB bearing bracket 6B. The FB through hole 6D4 is used to mount the FA radial probe 6O. The FA open groove 6C3 and the FB open groove 6D3 form a rectangular groove for fixing the a radial magnetic bearing stator 6F, and the a radial magnetic bearing stator coil 6E is wound on the a radial magnetic bearing stator 6F.

Referring to fig. 6B, 6C, and 6D, the FA axial magnetic bearing stator 6G and the FB axial magnetic bearing stator 6H have the same structure. The left end and the right end of the FA axial magnetic bearing stator 6G are respectively provided with an FC through hole 6G1 and an FD through hole 6G 2; one plate surface of the FA axial magnetic bearing stator 6G is a flat plate surface; the other plate surface of the FA axial magnetic bearing stator 6G is provided with an FA axial magnetic coil framework 6G3 and an FA axial magnetic coil groove 6G 4. The FC through hole 6G1 is used to mount the FB axial probe 6L. The FD through hole 6G2 is used for mounting the FA axial probe 6K. The FA axial magnetic bearing stator coil 6I is wound on the FA axial magnetic coil skeleton 6G3, and the FA axial magnetic bearing stator coil 6I is placed in the FA axial magnetic coil groove 6G 4. The left end and the right end of the FB axial magnetic bearing stator 6H are respectively provided with an FE through hole 6H1 and an FF through hole 6H 2; one plate surface of the FB axial magnetic bearing stator 6H is a flat plate surface; the other plate surface of the FB-axis magnetic bearing stator 6H is provided with an FB-axis magnetic coil framework 6H3 and an FB-axis magnetic coil groove 6H 4. The FE through hole 6H1 is used for mounting the FD axial probe 6N. The FF through hole 6H2 is used to mount the FC axial probe 6M. The FB axial magnetic bearing stator coil 6J is wound on the FB shaft magnetic coil bobbin 6H3, and the FB axial magnetic bearing stator coil 6J is placed in the FB shaft magnetic coil groove 6H 4.

B-diameter axial magnetic bearing integrated stator assembly 7

Referring to fig. 7, 7A and 7B, the B-radial-axial magnetic bearing integrated stator assembly 7 includes a GA bearing support 7A, GB bearing support 7B, GA radial probe support 7C, GB radial probe support 7D, B radial magnetic bearing stator coil 7E, B radial magnetic bearing stator 7F, GA axial magnetic bearing stator 7G, GB axial magnetic bearing stator 7H, GA axial magnetic bearing stator coil 7I, GB axial magnetic bearing stator coil 7J, GA axial probe 7K, GB axial probe 7L, GC axial probe 7M, GD axial probe 7N, GA radial probe 7O and GB radial probe 7P.

Referring to fig. 7B, the GA bearing bracket 7A is identical in structure to the GB bearing bracket 7B. The GA bearing support 7A is provided with a GA arm 7A1 and a GB arm 7A 2. The GB arm 7a2 is fixed to the upper end plate 7C1 of the GA radial probe carriage 7C. GB bearing support 7B is provided with GC support arm 7B1 and GD support arm 7B 2. And the GD support arm 7B2 is fixed on the lower end plate surface of the GB radial probe support 7D.

Referring to fig. 7B, the GA radial probe mount 7C is identical in structure to the GB radial probe mount 7D. The side plate face 7C2 of the GA radial probe holder 7C is provided with a GA through hole 7C4 and a GA opening groove 7C 3. The upper end plate surface 7C1 of the GA radial probe bracket 7C is fixed with the GB support arm 7A2 of the GA bearing bracket 7A; the lower end plate surface of the GA radial probe holder 7C is fixed to the upper end plate surface 7D1 of the GB radial probe holder 7D. GA through hole 7C4 is used to mount GB radial probe 7P. And a GB through hole 7D4 and a GB opening groove 7D3 are arranged on the side plate surface 7D2 of the GB radial probe bracket 7D. The lower end plate surface of GB radial probe holder 7D is fixed to GD support arm 7B2 of GB bearing holder 7B. GB through hole 7D4 is used to mount GA radial probe 7O. The GA open groove 7C3 and the GB open groove 7D3 form a rectangular groove for fixing the B radial magnetic bearing stator 7F, and the B radial magnetic bearing stator coil 7E is wound on the B radial magnetic bearing stator 7F.

Referring to fig. 7B, 7C, and 7D, the GA axial magnetic bearing stator 7G has the same structure as the GB axial magnetic bearing stator 7H. The left end and the right end of the GA axial magnetic bearing stator 7G are respectively provided with a GC through hole 7G1 and a GD through hole 7G 2; one plate surface of the GA axial magnetic bearing stator 7G is a flat plate surface; the other plate surface of the GA axial magnetic bearing stator 7G is provided with a GA shaft magnetic coil framework 7G3 and a GA shaft magnetic coil groove 7G 4. The GC through hole 7G1 is used to mount the GB axial probe 7L. The GD through hole 7G2 is used for mounting the GA axial probe 7K. The GA axial magnetic bearing stator coil 7I is wound on the GA axial magnetic coil bobbin 7G3, and the GA axial magnetic bearing stator coil 7I is placed in the GA axial magnetic coil groove 7G 4. The left end and the right end of the GB axial magnetic bearing stator 7H are respectively provided with a GE through hole 7H1 and a GF through hole 7H 2; one plate surface of the GB axial magnetic bearing stator 7H is a flat plate surface; the other plate surface of the GB axial magnetic bearing stator 7H is provided with a GB shaft magnetic coil framework 7H3 and a GB shaft magnetic coil groove 7H 4. The GE through hole 7H1 is used to mount the GD axial probe 7N. The GF through hole 7H2 is used to mount the GC axial probe 7M. A GB axial magnetic bearing stator coil 7J is wound on the GB axial magnetic coil bobbin 7H3, and the GB axial magnetic bearing stator coil 7J is placed in the GB axial magnetic coil groove 7H 4.

C-diameter axial magnetic bearing integrated stator assembly 8

Referring to fig. 8, 8A and 8B, the C-radial axial magnetic bearing integrated stator assembly 8 includes an HA bearing support 8A, HB bearing support 8B, HA radial probe support 8C, HB radial probe support 8D, C radial magnetic bearing stator coil 8E, C radial magnetic bearing stator 8F, HA axial magnetic bearing stator 8G, HB axial magnetic bearing stator 8H, HA axial magnetic bearing stator coil 8I, HB axial magnetic bearing stator coil 8J, HA axial probe 8K, HB axial probe 8L, HC axial probe 8M, HD axial probe 8N, HA radial probe 8O and HB radial probe 8P.

Referring to fig. 8B, HA bearing bracket 8A is identical in structure to HB bearing bracket 8B. HA support arm 8A1 and HB support arm 8A2 are arranged on HA bearing support 8A. The HB support arm 8A2 is fixed to the upper end plate 8C1 of HA radial probe support 8C. The HB bearing support 8B is provided with an HC support arm 8B1 and an HD support arm 8B 2. HD mounting arm 8B2 is fixed to the lower end plate of HB radial probe holder 8D.

Referring to fig. 8B, HA radial probe mount 8C is identical in structure to HB radial probe mount 8D. The side plate surface 8C2 of the HA radial probe bracket 8C is provided with an HA through hole 8C4 and an HA opening groove 8C 3. An upper end plate surface 8C1 of the HA radial probe bracket 8C is fixed with an HB support arm 8A2 of the HA bearing bracket 8A; the lower end plate surface of the HA radial probe holder 8C is fixed to the upper end plate surface 8D1 of the HB radial probe holder 8D. HA through hole 8C4 is used to mount HB radial probe 8P. An HB through hole 8D4 and an HB opening groove 8D3 are arranged on the side plate surface 8D2 of the HB radial probe support 8D. The lower end plate surface of the HB radial probe holder 8D is fixed to the HD arm 8B2 of the HB bearing holder 8B. HB thru-hole 8D4 is used to mount HA radial probe 8O. The HA open groove 8C3 and the HB open groove 8D3 are formed in a rectangular shape for fixing the C radial magnetic bearing stator 8F, and the C radial magnetic bearing stator coil 8E is wound on the C radial magnetic bearing stator 8F.

Referring to fig. 8B, 8C, and 8D, the HA axial magnetic bearing stator 8G and the HB axial magnetic bearing stator 8H have the same structure. The left end and the right end of the HA axial magnetic bearing stator 8G are respectively provided with an HC through hole 8G1 and an HD through hole 8G 2; one plate surface of the HA axial magnetic bearing stator 8G is a flat plate surface; the other plate surface of the HA axial magnetic bearing stator 8G is provided with an HA axial magnetic coil framework 8G3 and an HA axial magnetic coil groove 8G 4. The HC through hole 8G1 is used to mount the HB axial probe 8L. The HD through hole 8G2 is used to mount the HA axial probe 8K. The HA axial magnetic bearing stator coil 8I is wound on the HA axial magnetic coil bobbin 8G3, and the HA axial magnetic bearing stator coil 8I is placed in the HA axial magnetic coil groove 8G 4. The left end and the right end of the HB axial magnetic bearing stator 8H are respectively provided with an HE through hole 8H1 and an HF through hole 8H 2; one plate surface of the HB axial magnetic bearing stator 8H is a flat plate surface; the other plate surface of the HB axial magnetic bearing stator 8H is provided with an HB axial magnetic coil framework 8H3 and an HB axial magnetic coil groove 8H 4. HE through hole 8H1 is used to mount HD axial probe 8N. The HF through hole 8H2 is used to mount the HC axial probe 8M. An HB axial magnetic bearing stator coil 8J is wound on the HB axial magnetic coil skeleton 8H3, and the HB axial magnetic bearing stator coil 8J is arranged in the HB axial magnetic coil groove 8H 4.

D-diameter axial magnetic bearing integrated stator assembly 9

Referring to fig. 9, 9A and 9B, the D-radial-axial magnetic bearing integrated stator assembly 9 includes an IA bearing support 9A, IB bearing support 9B, IA radial probe support 9C, IB radial probe support 9D, D radial magnetic bearing stator coil 9E, D radial magnetic bearing stator 9F, IA axial magnetic bearing stator 9G, IB axial magnetic bearing stator 9H, IA axial magnetic bearing stator coil 9I, IB axial magnetic bearing stator coil 9J, IA axial probe 9K, IB axial probe 9L, IC axial probe 9M, ID axial probe 9N, IA radial probe 9O and IB radial probe 9P.

Referring to fig. 9B, the IA bearing bracket 9A and the IB bearing bracket 9B have the same structure. An IA supporting arm 9A1 and an IB supporting arm 9A2 are arranged on the IA bearing support 9A. The IB arm 9A2 is fixed to the upper end plate 9C1 of the IA radial probe carrier 9C. The IB bearing holder 9B is provided with an IC arm 9B1 and an ID arm 9B 2. The ID arm 9B2 is fixed to the lower end plate surface of the IB radial probe holder 9D.

Referring to FIG. 9B, the IA radial probe carrier 9C is identical in construction to the IB radial probe carrier 9D. The side plate surface 9C2 of the IA radial probe bracket 9C is provided with an IA through hole 9C4 and an IA opening groove 9C 3. An upper end plate surface 9C1 of the IA radial probe bracket 9C is fixed with an IB support arm 9A2 of the IA bearing bracket 9A; the lower end plate surface of the IA radial probe holder 9C is fixed to the upper end plate surface 9D1 of the IB radial probe holder 9D. The IA through hole 9C4 is used for mounting the IB radial probe 9P. An IB through hole 9D4 and an IB opening groove 9D3 are arranged on the side plate surface 9D2 of the IB radial probe bracket 9D. The lower end plate surface of the IB radial probe holder 9D is fixed to the ID arm 9B2 of the IB bearing holder 9B. IB through hole 9D4 is used to mount IA radial probe 9O. The IA open groove 9C3 and the IB open groove 9D3 form a rectangular groove for fixing the D radial magnetic bearing stator 9F, and the D radial magnetic bearing stator coil 9E is wound on the D radial magnetic bearing stator 9F.

Referring to fig. 9B, 9C, and 9D, the IA axial magnetic bearing stator 9G and the IB axial magnetic bearing stator 9H have the same structure. The left end and the right end of the IA axial magnetic bearing stator 9G are respectively provided with an IC through hole 9G1 and an ID through hole 9G 2; one plate surface of the IA axial magnetic bearing stator 9G is a flat plate surface; the other plate surface of the IA axial magnetic bearing stator 9G is provided with an IA shaft magnetic coil framework 9G3 and an IA shaft magnetic coil groove 9G 4. The IC through hole 9G1 is used for mounting the IB axial probe 9L. The ID through hole 9G2 is used for mounting the IA axial probe 9K. An IA axial magnetic bearing stator coil 9I is wound on the IA shaft magnetic coil skeleton 9G3, and the IA axial magnetic bearing stator coil 9I is arranged in the IA shaft magnetic coil groove 9G 4. IE through holes 9H1 and IF through holes 9H2 are respectively arranged at the left end and the right end of the IB axial magnetic bearing stator 9H; one plate surface of the IB axial magnetic bearing stator 9H is a flat plate surface; the other plate surface of the IB axial magnetic bearing stator 9H is provided with an IB shaft magnetic coil framework 9H3 and an IB shaft magnetic coil groove 9H 4. IE through hole 9H1 is used to mount ID axial probe 9N. The IF through hole 9H2 is used for mounting the IC axial probe 9M. The IB axial magnetic bearing stator coil 9J is wound on the IB axial magnetic coil bobbin 9H3, and the IB axial magnetic bearing stator coil 9J is disposed in the IB axial magnetic coil groove 9H 4.

Description of the relationship of motion

Under the condition of electrification, the radial and axial magnetic bearing integrated stator components (6, 7, 8 and 9) are electrified to enable the radial and axial magnetic bearing integrated rotor component (2) to be suspended, and then the radial and axial magnetic bearing integrated rotor component (2) is rotated by the single-shaft turntable driving mechanism (5), so that complete suspension rotation is realized.

Claims (3)

1. The utility model provides an ultrastable hyperstatic unipolar revolving stage of initiative magnetic suspension bearing support which characterized in that: the turntable comprises an A-diameter axial magnetic bearing integrated stator component (6), a B-diameter axial magnetic bearing integrated stator component (7), a C-diameter axial magnetic bearing integrated stator component (8), a D-diameter axial magnetic bearing integrated stator component (9), a radial axial magnetic bearing integrated rotor component (2), a disc body (3), a base (4) and a single-shaft turntable driving mechanism (5); the disk body (3) and a plurality of radial-axial magnetic bearing integrated rotor assemblies (2) distributed along the circumference of the disk body (3) form a magnetic suspension rotating platform (1);

the radial and axial magnetic bearing integrated rotor assembly (2) is composed of a rotor bracket (2A), a rotor lamination (2B), a rotor upper pressure plate (2C) and a rotor lower pressure plate (2D);

a BA support arm (2A1) and a BB support arm (2A2) are arranged on one side of the rotor support (2A), and a BA groove (2A3) is formed between the BA support arm (2A1) and the BB support arm (2A 2); the other side of the rotor bracket (2A) is provided with a BC support arm (2A4) and a BD support arm (2A5), and a BB groove (2A6) is arranged between the BC support arm (2A4) and the BD support arm (2A 5); the BA groove (2A3) is used for placing an outer edge surface (3B) of the disc body (3), and the BA support arm (2A1) and the BB support arm (2A2) are fixed on the disc body (3) through screws; the BB groove (2A6) is used for placing a rotor lamination (2B); a rotor upper pressure plate (2C) is fixed on the BC support arm (2A4) by a screw; a rotor lower pressing plate (2D) is fixed on the BD supporting arm (2A5) through a screw;

a plurality of radial-axial magnetic bearing integrated rotor assemblies (2) are distributed along the circumference of the disc body (3);

the disc body (3) is of a flat circular disc structure, a central through hole (3A) is formed in the center of the disc body (3), and the central through hole (3A) is used for allowing one end of a fifth rotating shaft (5A) of the single-shaft rotary table driving mechanism (5) to penetrate through; the edge of the disc body (3) is an outer edge surface (3B), and a plurality of radial and axial magnetic bearing integrated rotor assemblies (2) which are distributed circumferentially are mounted on the outer edge surface (3B);

the disk body (3) and a magnetic suspension rotating platform (1) formed by a plurality of radial and axial magnetic bearing integrated rotor assemblies (2) distributed along the circumference of the disk body (3); the magnetic suspension rotating platform (1) is driven by a turntable driving motor assembly (5) to rotate;

a DA through hole (4A) is formed in the center of the base (4), a DA boss (4B) is arranged above the DA through hole (4A), a DB boss (4E) is arranged below the DA through hole (4A), and a DC boss (4F) is arranged in the DA through hole (4A); a countersunk head cavity (4C) and an outer boss (4D) are arranged above the base (4), and four magnetic suspension bearing stator assemblies, namely an A radial axial magnetic bearing integrated stator assembly (6), a B radial axial magnetic bearing integrated stator assembly (7), a C radial axial magnetic bearing integrated stator assembly (8) and a D radial axial magnetic bearing integrated stator assembly (9), are uniformly distributed on the outer boss (4D); be equipped with the blind hole on the outer fringe face (4H) of base (4) of installing magnetic suspension bearing stator module department, promptly:

DA blind holes are formed in the outer edge surface (4H) of the base (4) at the position of the integrated stator assembly (6) of the A-diameter axial magnetic bearing; the DA blind hole is used for mounting one end of a first rotating shaft (10A) of the first driving mechanism (10);

a DB blind hole (4G2) is arranged on the outer edge surface (4H) of the base (4) at the position of the integrated stator component (7) of the radial-axial magnetic bearing B; the DB blind hole (4G2) is used for mounting one end of a third rotating shaft (12A) of a third driving mechanism (12);

a DC blind hole (4G3) is arranged on the outer edge surface (4H) of the base (4) at the position of the integrated stator component (8) of the C-diameter axial magnetic bearing; the DC blind hole (4G3) is used for mounting one end of a second rotating shaft (11A) of the second driving mechanism (11);

a DD blind hole is arranged on the outer edge surface (4H) of the base (4) at the position of the integrated stator component (9) of the D-diameter axial magnetic bearing; the DD blind hole is used for mounting one end of a fourth rotating shaft (13A) of a fourth driving mechanism (13);

the base (4) is arranged below the disc body (3);

the single-shaft turntable driving mechanism (5) comprises a rotating shaft (5A), a motor stator (5B), an EA coil (5C), a rotor baffle ring (5E), a sheath (5F) and a permanent magnet (5G);

the rotating shaft (5A) is provided with an EA shaft section (5A1), an EB shaft section (5A2), an EC shaft section (5A3) and a shaft shoulder (5A 4); a shaft shoulder (5A4) is arranged between the EA shaft section (5A1) and the EB shaft section (5A 2);

the EA shaft section (5A1) is used for passing through the central through hole (3A) of the disc body (3) and is fixedly installed with the disc body (3);

the upper end of the EA coil (5C) is placed on the EB shaft section (5A 2);

the EC shaft section (5A3) is sleeved with a permanent magnet (5G), the outer part of the permanent magnet (5G) is sleeved with a sheath (5F), the upper ends of the permanent magnet (5G) and the sheath (5F) are tightly propped against the lower end face of the EB shaft section (5A2), and the lower ends of the permanent magnet (5G) and the sheath (5F) are provided with a rotor baffle ring (5E); a motor stator (5B) is sleeved outside the sheath (5F);

coil frameworks (5D) are uniformly distributed on the inner circumference of the motor stator (5B), coil grooves (5D1) are formed between every two adjacent coil frameworks (5D), and coils (5C) are placed in the coil grooves (5D 1);

the motor stator (5B) is fixedly arranged in the DA through hole (4A) of the base (4);

the A-diameter axial magnetic bearing integrated stator component (6) comprises an FA bearing support (6A), an FB bearing support (6B), an FA radial probe support (6C), an FB radial probe support (6D), an A-radial magnetic bearing stator coil (6E), an A-radial magnetic bearing stator (6F), an FA axial magnetic bearing stator (6G), an FB axial magnetic bearing stator (6H), an FA axial magnetic bearing stator coil (6I), an FB axial magnetic bearing stator coil (6J), an FA axial probe (6K), an FB axial probe (6L), an FC axial probe (6M), an FD axial probe (6N), an FA radial probe (6O) and an FB radial probe (6P);

the FA bearing support (6A) and the FB bearing support (6B) have the same structure; an FA supporting arm (6A1) and an FB supporting arm (6A2) are arranged on the FA bearing support (6A); the FB support arm (6A2) is fixed on the upper end plate surface (6C1) of the FA radial probe bracket (6C); the FB bearing support (6B) is provided with an FC support arm (6B1) and an FD support arm (6B 2); the FD support arm (6B2) is fixed on the lower end plate surface of the FB radial probe bracket (6D);

the FA radial probe bracket (6C) and the FB radial probe bracket (6D) have the same structure; an FA through hole (6C4) and an FA opening groove (6C3) are formed in a side plate surface (6C2) of the FA radial probe bracket (6C); the upper end plate surface (6C1) of the FA radial probe bracket (6C) is fixed with an FB support arm (6A2) of the FA bearing bracket (6A); the lower end plate surface of the FA radial probe bracket (6C) is fixed with the upper end plate surface (6D1) of the FB radial probe bracket (6D); the FA through hole (6C4) is used for mounting the FB radial probe (6P); an FB through hole (6D4) and an FB opening groove (6D3) are formed in a side plate surface (6D2) of the FB radial probe support (6D); the lower end plate surface of the FB radial probe bracket (6D) is fixed with an FD support arm (6B2) of the FB bearing bracket (6B); the FB through hole (6D4) is used for mounting the FA radial probe (6O); the FA open groove (6C3) and the FB open groove (6D3) are formed into a rectangular groove in a conformal mode, the rectangular groove is used for fixing an A radial magnetic bearing stator (6F), and an A radial magnetic bearing stator coil (6E) is wound on the A radial magnetic bearing stator (6F);

the FA axial magnetic bearing stator (6G) and the FB axial magnetic bearing stator (6H) have the same structure; the left end and the right end of the FA axial magnetic bearing stator (6G) are respectively provided with an FC through hole (6G1) and an FD through hole (6G 2); one plate surface of the FA axial magnetic bearing stator (6G) is a flat plate surface; the other plate surface of the FA axial magnetic bearing stator (6G) is provided with an FA axial magnetic coil framework (6G3) and an FA axial magnetic coil groove (6G 4); the FC through hole (6G1) is used for mounting the FB axial probe (6L); the FD through hole (6G2) is used for installing an FA axial probe (6K); an FA axial magnetic bearing stator coil (6I) is wound on the FA axial magnetic coil framework (6G3), and the FA axial magnetic bearing stator coil (6I) is arranged in the FA axial magnetic coil groove (6G 4); the left end and the right end of the FB axial magnetic bearing stator (6H) are respectively provided with an FE through hole (6H1) and an FF through hole (6H 2); one plate surface of the FB axial magnetic bearing stator (6H) is a flat plate surface; the other plate surface of the FB axial magnetic bearing stator (6H) is provided with an FB shaft magnetic coil framework (6H3) and an FB shaft magnetic coil groove (6H 4); the FE through hole (6H1) is used for installing the FD axial probe 6N; the FF through hole (6H2) is used for installing an FC axial probe (6M); an FB axial magnetic bearing stator coil (6J) is wound on the FB axial magnetic coil framework (6H3), and the FB axial magnetic bearing stator coil (6J) is arranged in the FB axial magnetic coil groove (6H 4);

the B-radial-axial magnetic bearing integrated stator assembly (7) comprises a GA bearing support (7A), a GB bearing support (7B), a GA radial probe support (7C), a GB radial probe support (7D), a B-radial magnetic bearing stator coil (7E), a B-radial magnetic bearing stator (7F), a GA axial magnetic bearing stator (7G), a GB axial magnetic bearing stator (7H), a GA axial magnetic bearing stator coil (7I), a GB axial magnetic bearing stator coil (7J), a GA axial probe (7K), a GB axial probe (7L), a GC axial probe (7M), a GD axial probe (7N), a GA radial probe (7O) and a GB radial probe (7P);

the GA bearing support (7A) and the GB bearing support (7B) have the same structure; a GA support arm (7A1) and a GB support arm (7A2) are arranged on the GA bearing support (7A); the GB support arm (7A2) is fixed on the upper end plate surface (7C1) of the GA radial probe bracket (7C); a GC support arm (7B1) and a GD support arm (7B2) are arranged on the GB bearing support (7B); the GD support arm (7B2) is fixed on the lower end plate surface of the GB radial probe bracket (7D);

the GA radial probe bracket (7C) and the GB radial probe bracket (7D) have the same structure; a GA through hole (7C4) and a GA opening groove (7C3) are formed in the side plate surface (7C2) of the GA radial probe bracket (7C); the upper end plate surface (7C1) of the GA radial probe bracket (7C) is fixed with a GB support arm (7A2) of the GA bearing bracket (7A); the lower end plate surface of the GA radial probe bracket (7C) is fixed with the upper end plate surface (7D1) of the GB radial probe bracket (7D); the GA through hole (7C4) is used for mounting a GB radial probe (7P); a GB through hole (7D4) and a GB opening groove (7D3) are formed in a side plate surface (7D2) of the GB radial probe bracket (7D); the lower end plate surface of the GB radial probe bracket (7D) is fixed with a GD support arm (7B2) of the GB bearing bracket (7B); the GB through hole (7D4) is used for installing the GA radial probe (7O); the GA open groove (7C3) and the GB open groove (7D3) are formed into a rectangular groove in a conformal mode, the rectangular groove is used for fixing a B radial magnetic bearing stator (7F), and the B radial magnetic bearing stator coil (7E) is wound on the B radial magnetic bearing stator (7F);

the structure of the GA axial magnetic bearing stator (7G) is the same as that of the GB axial magnetic bearing stator (7H); the left end and the right end of the GA axial magnetic bearing stator (7G) are respectively provided with a GC through hole (7G1) and a GD through hole (7G 2); one plate surface of the GA axial magnetic bearing stator (7G) is a flat plate surface; the other plate surface of the GA axial magnetic bearing stator (7G) is provided with a GA shaft magnetic coil framework (7G3) and a GA shaft magnetic coil groove (7G 4); the GC through hole (7G1) is used for mounting a GB axial probe (7L); the GD through hole (7G2) is used for mounting a GA axial probe (7K); a GA axial magnetic bearing stator coil (7I) is wound on the GA axial magnetic coil framework (7G3), and the GA axial magnetic bearing stator coil (7I) is arranged in the GA axial magnetic coil groove (7G 4); the left end and the right end of the GB axial magnetic bearing stator (7H) are respectively provided with a GE through hole (7H1) and a GF through hole (7H 2); one plate surface of the GB axial magnetic bearing stator (7H) is a flat plate surface; the other plate surface of the GB axial magnetic bearing stator (7H) is provided with a GB shaft magnetic coil framework (7H3) and a GB shaft magnetic coil groove (7H 4); the GE through hole (7H1) is used for installing a GD axial probe (7N); the GF through hole (7H2) is used for installing a GC axial probe (7M); a GB axial magnetic bearing stator coil (7J) is wound on the GB axial magnetic coil framework (7H3), and the GB axial magnetic bearing stator coil (7J) is arranged in the GB axial magnetic coil groove (7H 4);

the C-diameter axial magnetic bearing integrated stator component (8) comprises an HA bearing support (8A), an HB bearing support (8B), an HA radial probe support (8C), an HB radial probe support (8D), a C radial magnetic bearing stator coil (8E), a C radial magnetic bearing stator (8F), an HA axial magnetic bearing stator (8G), an HB axial magnetic bearing stator (8H), an HA axial magnetic bearing stator coil (8I), an HB axial magnetic bearing stator coil (8J), an HA axial probe (8K), an HB axial probe (8L), an HC axial probe (8M), an HD axial probe (8N), an HA radial probe (8O) and an HB radial probe (8P);

the HA bearing support (8A) and the HB bearing support (8B) have the same structure; an HA support arm (8A1) and an HB support arm (8A2) are arranged on the HA bearing support (8A); the HB support arm (8A2) is fixed on the upper end plate surface (8C1) of the HA radial probe bracket (8C); an HC support arm (8B1) and an HD support arm (8B2) are arranged on the HB bearing support (8B); the HD support arm (8B2) is fixed on the lower end plate surface of the HB radial probe support (8D);

the HA radial probe bracket (8C) and the HB radial probe bracket (8D) have the same structure; an HA through hole (8C4) and an HA opening groove (8C3) are formed in a side plate surface (8C2) of the HA radial probe support (8C); an upper end plate surface (8C1) of the HA radial probe bracket (8C) is fixed with an HB support arm (8A2) of the HA bearing bracket (8A); the lower end plate surface of the HA radial probe bracket 8C is fixed with the upper end plate surface 8D1 of the HB radial probe bracket 8D; the HA through hole (8C4) is used for installing an HB radial probe (8P); an HB through hole (8D4) and an HB opening groove (8D3) are formed in the side plate surface (8D2) of the HB radial probe support (8D); the lower end plate surface of the HB radial probe support (8D) is fixed with an HD support arm (8B2) of the HB bearing support (8B); the HB through hole (8D4) is used for mounting an HA radial probe (8O); the HA open groove (8C3) and the HB open groove (8D3) are formed into a rectangular groove in a conformal manner, the rectangular groove is used for fixing a C radial magnetic bearing stator (8F), and a C radial magnetic bearing stator coil (8E) is wound on the C radial magnetic bearing stator (8F);

the HA axial magnetic bearing stator (8G) and the HB axial magnetic bearing stator (8H) have the same structure; the left end and the right end of the HA axial magnetic bearing stator (8G) are respectively provided with an HC through hole (8G1) and an HD through hole (8G 2); one plate surface of the HA axial magnetic bearing stator (8G) is a flat plate surface; the other plate surface of the HA axial magnetic bearing stator (8G) is provided with an HA axial magnetic coil framework (8G3) and an HA axial magnetic coil groove (8G 4); the HC through hole (8G1) is used for installing an HB axial probe (8L); the HD through hole (8G2) is used for mounting an HA axial probe (8K); an HA axial magnetic bearing stator coil (8I) is wound on the HA axial magnetic coil framework (8G3), and the HA axial magnetic bearing stator coil (8I) is arranged in the HA axial magnetic coil groove (8G 4); the left end and the right end of the HB axial magnetic bearing stator (8H) are respectively provided with an HE through hole (8H1) and an HF through hole (8H 2); one plate surface of the HB axial magnetic bearing stator (8H) is a flat plate surface; the other plate surface of the HB axial magnetic bearing stator (8H) is provided with an HB axial magnetic coil framework (8H3) and an HB axial magnetic coil groove (8H 4); the HE through hole (8H1) is used for mounting an HD axial probe (8N); the HF through hole (8H2) is used for mounting an HC axial probe (8M); an HB axial magnetic bearing stator coil (8J) is wound on the HB axial magnetic coil framework (8H3), and the HB axial magnetic bearing stator coil (8J) is arranged in the HB axial magnetic coil groove (8H 4);

the D-diameter axial magnetic bearing integrated stator component (9) comprises an IA bearing support (9A), an IB bearing support (9B), an IA radial probe support (9C), an IB radial probe support (9D), a D-diameter axial magnetic bearing stator coil (9E), a D-diameter axial magnetic bearing stator (9F), an IA axial magnetic bearing stator (9G), an IB axial magnetic bearing stator (9H), an IA axial magnetic bearing stator coil (9I), an IB axial magnetic bearing stator coil (9J), an IA axial probe (9K), an IB axial probe (9L), an IC axial probe (9M), an ID axial probe (9N), an IA radial probe (9O) and an IB radial probe (9P);

the IA bearing support (9A) and the IB bearing support (9B) have the same structure; an IA support arm (9A1) and an IB support arm (9A2) are arranged on the IA bearing support (9A); the IB supporting arm (9A2) is fixed on the upper end plate surface (9C1) of the IA radial probe bracket (9C); an IC arm (9B1) and an ID arm (9B2) are arranged on the IB bearing support (9B); the ID support arm (9B2) is fixed on the lower end plate surface of the IB radial probe bracket (9D);

the IA radial probe bracket (9C) and the IB radial probe bracket (9D) have the same structure; an IA through hole (9C4) and an IA opening groove (9C3) are arranged on a side plate surface (9C2) of the IA radial probe bracket (9C); an upper end plate surface (9C1) of the IA radial probe bracket (9C) is fixed with an IB support arm (9A2) of the IA bearing bracket (9A); the lower end plate surface of the IA radial probe bracket (9C) is fixed with the upper end plate surface (9D1) of the IB radial probe bracket (9D); the IA through hole (9C4) is used for installing an IB radial probe (9P); an IB through hole (9D4) and an IB opening groove (9D3) are formed in a side plate surface (9D2) of the IB radial probe bracket (9D); the lower end plate surface of the IB radial probe bracket (9D) is fixed with an ID support arm (9B2) of the IB bearing bracket (9B); the IB through hole (9D4) is used for mounting the IA radial probe (9O); the IA open groove (9C3) and the IB open groove (9D3) are formed into a rectangular groove in a conformal mode, the rectangular groove is used for fixing a D radial magnetic bearing stator (9F), and the D radial magnetic bearing stator coil (9E) is wound on the D radial magnetic bearing stator (9F);

the IA axial magnetic bearing stator (9G) and the IB axial magnetic bearing stator (9H) have the same structure; the left end and the right end of the IA axial magnetic bearing stator (9G) are respectively provided with an IC through hole (9G1) and an ID through hole (9G 2); one plate surface of the IA axial magnetic bearing stator (9G) is a flat plate surface; the other plate surface of the IA axial magnetic bearing stator (9G) is provided with an IA shaft magnetic coil framework (9G3) and an IA shaft magnetic coil groove (9G 4); the IC through hole (9G1) is used for mounting the IB axial probe (9L); the ID through hole (9G2) is used for mounting the IA axial probe (9K); an IA axial magnetic bearing stator coil (9I) is wound on the IA axial magnetic coil framework (9G3), and the IA axial magnetic bearing stator coil (9I) is arranged in the IA axial magnetic coil groove (9G 4); IE through holes (9H1) and IF through holes (9H2) are respectively arranged at the left end and the right end of the IB axial magnetic bearing stator (9H); one plate surface of the IB axial magnetic bearing stator (9H) is a flat plate surface; the other plate surface of the IB axial magnetic bearing stator (9H) is provided with an IB shaft magnetic coil framework (9H3) and an IB shaft magnetic coil groove (9H 4); IE through hole (9H1) is used for installing ID axial probe (9N); the IF through hole (9H2) is used for mounting an IC axial probe (9M); an IB axial magnetic bearing stator coil (9J) is wound on the IB axial magnetic coil framework (9H3), and the IB axial magnetic bearing stator coil (9J) is arranged in the IB axial magnetic coil groove (9H 4).

2. The ultra-stable and ultra-static single-axis turntable supported by the active magnetic suspension bearing as claimed in claim 1, wherein: in order to enable the A-radial-axial magnetic bearing integrated stator assembly (6), the B-radial-axial magnetic bearing integrated stator assembly (7), the C-radial-axial magnetic bearing integrated stator assembly (8) and the D-radial-axial magnetic bearing integrated stator assembly (9) with the same structure to be symmetrically distributed along the magnetic suspension rotating platform (1), the A-radial-axial magnetic bearing integrated stator assembly (6), the B-radial-axial magnetic bearing integrated stator assembly (7), the C-radial-axial magnetic bearing integrated stator assembly (8) and the D-radial-axial magnetic bearing integrated stator assembly (9) are designed into an arc-shaped structure.

3. The ultra-stable and ultra-static single-axis turntable supported by the active magnetic suspension bearing as claimed in claim 1, wherein: the superstable hyperstatic single-shaft rotary table supported by the active magnetic suspension bearing is characterized in that under the electrified condition, the radial and axial magnetic bearing integrated stator assemblies (6, 7, 8 and 9) are electrified firstly to enable the radial and axial magnetic bearing integrated rotor assembly (2) to be suspended, and then the radial and axial magnetic bearing integrated rotor assembly (2) is rotated by the single-shaft rotary table driving mechanism (5), so that complete suspension rotation is realized.

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