CN111668950A - Two-stage composite direct-drive motor - Google Patents

Two-stage composite direct-drive motor Download PDF

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Publication number
CN111668950A
CN111668950A CN201910166710.4A CN201910166710A CN111668950A CN 111668950 A CN111668950 A CN 111668950A CN 201910166710 A CN201910166710 A CN 201910166710A CN 111668950 A CN111668950 A CN 111668950A
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magnetic
ring assembly
ring
assembly
magnetic ring
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CN201910166710.4A
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王向东
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Jiangsu Jinling Permanent Magnet Industry Research Institute Co ltd
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Jiangsu Jinling Permanent Magnet Industry Research Institute Co ltd
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Priority to CN201910166710.4A priority Critical patent/CN111668950A/en
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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K1/00Details of the magnetic circuit
    • H02K1/06Details of the magnetic circuit characterised by the shape, form or construction
    • H02K1/22Rotating parts of the magnetic circuit
    • H02K1/27Rotor cores with permanent magnets
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K16/00Machines with more than one rotor or stator
    • H02K16/04Machines with one rotor and two stators
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K49/00Dynamo-electric clutches; Dynamo-electric brakes
    • H02K49/10Dynamo-electric clutches; Dynamo-electric brakes of the permanent-magnet type
    • H02K49/102Magnetic gearings, i.e. assembly of gears, linear or rotary, by which motion is magnetically transferred without physical contact

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Permanent Magnet Type Synchronous Machine (AREA)

Abstract

The invention discloses a two-stage composite direct-drive motor which comprises a winding assembly (1), an inner magnetic ring assembly (2), a modulation ring assembly (3), an outer magnetic ring assembly (4) and an output shaft (5), wherein the four are coaxially sleeved together; the winding assembly (1) is positioned in the inner cavity of the inner magnetic ring assembly (2) and is separated from the inner magnetic ring assembly (2) by an air gap; the inner magnetic ring assembly (2) is positioned in the inner cavity of the modulation ring assembly (3) and is separated from the modulation ring assembly (3) by an air gap; the modulation ring assembly (3) is positioned in the inner cavity of the outer magnetic ring assembly (4) and is separated from the outer magnetic ring assembly (4) by an air gap; the winding assembly (1) is electrified with alternating current to generate a rotating magnetic field, the rotating magnetic field generates acting force with the inner magnetic ring assembly (2), the modulation ring assembly (3) and the outer magnetic ring assembly (4), and kinetic energy is output through the output shaft (5). The invention has simple structure and small volume, can realize low-speed output, can meet the requirements of various low-speed loads, and is suitable for popularization and use.

Description

Two-stage composite direct-drive motor
Technical Field
The invention relates to the technical field of permanent magnet motors, in particular to a composite direct drive motor which is simple in structure, small in size and capable of realizing low-rotating-speed and large-torque output.
Background
The permanent magnet motor is more and more popular with users due to high efficiency and high power factor, but in practical industrial application, a large number of application scenes need environments with large torque and low rotating speed, such as a new energy automobile driving system, an oil extraction system of an oil field head-knocking machine, a belt type conveying system, a chain type conveying system, a wind power generation system and the like; there are generally two solutions for these environments: the first scheme is as follows: adopting a (permanent magnet) motor, a speed reducer and a load; scheme II: a permanent magnet motor and load are called permanent magnet direct drive mode for short. In the first scheme, a transmission link is added, and particularly, the failure rate of a speed reducer link is high. Scheme two the only way of the permanent magnet motor direct drive mode for low rotating speed is to increase the number of pole pairs of the motor, so that the result is that the number of pole pairs is large, the motor has a complex structure, a large volume and high cost; or the technology of integrating the permanent magnet gear and the permanent magnet motor is adopted, the number of pole pairs is small, the rotating speed is still high due to the limitation of the size or the process, and the requirement of low rotating speed load cannot be met.
Disclosure of Invention
The invention aims to solve the problems in the prior art, and provides a composite direct-drive motor which is simple in structure, small in size and capable of realizing low-rotating-speed and large-torque output.
The invention aims to solve the problems by the following technical scheme:
the utility model provides a compound motor that directly drives of second grade, includes winding assembly, interior magnetic ring assembly, modulation ring assembly, outer magnetic ring assembly and the output shaft that relative set up, its characterized in that: the winding assembly, the inner magnetic ring assembly, the modulation ring assembly and the outer magnetic ring assembly are coaxially sleeved together; the winding assembly is positioned in the inner cavity of the inner magnetic ring assembly and is separated from the inner magnetic ring assembly by an air gap; the inner magnetic ring assembly is positioned in the inner cavity of the modulation ring assembly and is separated from the modulation ring assembly by an air gap; the modulation ring assembly is positioned in the inner cavity of the outer magnetic ring assembly and is separated from the outer magnetic ring assembly by an air gap; the winding assembly consists of a coil winding and an iron core, and the number of pole pairs of the coil winding is p1The number of salient poles on the core is p3(ii) a The inner magnetic ring assembly consists of an inner ring permanent magnetic ring and an outer ring permanent magnetic ring, and the number of magnetic pole pairs of the inner ring permanent magnetic ring is p2And the magnetic pole pair number of the outer ring permanent magnetic ring is p4(ii) a Number of pole pairs p of coil winding1Number of salient poles p3And the number p of magnetic pole pairs of the inner ring permanent magnetic ring2Has a relationship of p1+p2=p3(ii) a The modulation ring assembly is composed of magnetic conductive blocks and non-magnetic conductive blocks arranged at intervals, wherein the number of the magnetic conductive blocks is p6(ii) a External magnetic ring assemblyThe number of pole pairs of the permanent magnetic ring is p5(ii) a Magnetic pole pair number p of outer ring permanent magnetic ring4The number p of the magnetic conduction blocks in the modulation ring assembly6And the pole pair p of the permanent magnet ring of the outer magnet ring assembly5The relationship between is p4+p5=p6(ii) a When the winding assembly is electrified with alternating current, a rotating magnetic field is generated, the rotating magnetic field is modulated by the salient poles on the iron core, and the pole pair number of the generated space harmonic magnetic field is matched with the pole pair number of the inner ring permanent magnet ring in the inner ring magnetic ring assembly, so that an acting force is generated between the winding assembly and the inner ring magnetic ring assembly, and the electric energy is converted into kinetic energy to drive the inner ring magnetic ring assembly to rotate; when the inner magnetic ring assembly rotates, the rotating magnetic field of the outer permanent magnetic ring is modulated by the magnetic conduction blocks on the modulation ring assembly, so that the pole pair number of the generated space harmonic magnetic field is matched with the pole pair number of the permanent magnetic ring of the outer magnetic ring assembly, an acting force is generated among the inner magnetic ring assembly, the modulation ring assembly and the outer magnetic ring assembly, and the kinetic energy is output through the output shaft.
The inner ring permanent magnet ring in the inner magnetic ring assembly passes through 2p2The N poles and the S poles of the block permanent magnets are uniformly arranged in the circumferential direction at intervals to form a magnetic pole pair number p2The magnetic ring of (2); or through 4p2The block permanent magnets are circumferentially arranged by adopting a Halbach array to form a magnetic pole pair number p2The magnetic ring.
An outer ring permanent magnet ring in the inner magnetic ring assembly passes through 2p4The N poles and the S poles of the block permanent magnets are uniformly arranged in the circumferential direction at intervals to form a magnetic pole pair number p4The magnetic ring of (2); or through 4p4The block permanent magnets are circumferentially arranged by adopting a Halbach array to form a magnetic pole pair number p4The magnetic ring.
The permanent magnet ring in the outer magnet ring assembly passes through 2p5The N poles and the S poles of the block permanent magnets are uniformly arranged in the circumferential direction at intervals to form a magnetic pole pair number p5The magnetic ring of (2); or through 4p5The block permanent magnets are circumferentially arranged by adopting a Halbach array to form a magnetic pole pair number p5The magnetic ring.
The winding assembly is fixed on the first end cover through the support shaft, and the inner magnetic ring assembly is installed on the support shaft through the first bearing, so that the inner magnetic ring assembly can rotate relative to the winding assembly.
The modulation ring assembly is used as a rotor and connected with the output shaft, and the output shaft outwards penetrates through a second bearing embedded in the second end cover and rotates relative to the second end cover through the second bearing.
The outer magnetic ring assembly, the first end cover and the second end cover are encircled to form a shell of the secondary composite direct drive motor, the outer magnetic ring assembly is located between the first end cover and the second end cover, and the end faces of the two ends of the outer magnetic ring assembly are respectively fixed on the inner wall of the end face of the first end cover and the inner wall of the end face of the second end cover.
The winding assembly can also be composed of a coil winding, a common iron core and a magnetic adjusting block, and the number of pole pairs of the coil winding is p1The number of the magnetic blocks is p3And the number p of pole pairs of the coil winding1And the number p of the magnetic blocks3And the number p of magnetic pole pairs of the inner ring permanent magnetic ring2Has a relationship of p1+p2=p3(ii) a When the winding assembly is electrified with alternating current, a rotating magnetic field is generated, the rotating magnetic field is modulated by the magnetic adjusting block, and the pole pair number of the generated space harmonic magnetic field is matched with the pole pair number of the inner ring permanent magnet ring in the inner ring magnetic ring assembly, so that an acting force is generated between the winding assembly and the inner ring magnetic ring assembly, and the electric energy is converted into kinetic energy to drive the inner ring magnetic ring assembly to rotate; when the inner magnetic ring assembly rotates, the rotating magnetic field of the outer permanent magnetic ring is modulated by the magnetic conduction blocks on the modulation ring assembly, so that the pole pair number of the generated space harmonic magnetic field is matched with the pole pair number of the permanent magnetic ring of the outer magnetic ring assembly, an acting force is generated among the inner magnetic ring assembly, the modulation ring assembly and the outer magnetic ring assembly, and the kinetic energy is output through the output shaft.
The magnetic adjusting blocks are uniformly distributed along the circumferential direction of the common iron core and tightly attached to the outer circumferential surface of the iron core, and gaps are reserved between the adjacent magnetic adjusting blocks.
Drawings
FIG. 1 is a schematic structural diagram of a two-stage composite direct drive motor according to an embodiment of the present invention;
FIG. 2 is a schematic cross-sectional view of FIG. 1;
FIG. 3 is a schematic structural view of a second embodiment of the two-stage composite direct drive motor of the present invention;
fig. 4 is a schematic cross-sectional structure of fig. 3.
Wherein: 1. a winding assembly; 1-1, coil winding; 1-2, iron core; 1-3, salient pole; 1-4, common iron core; 1-5, a magnetic adjusting block; 2. an inner magnetic ring assembly; 2-1, inner ring permanent magnetic ring; 2-2, outer ring permanent magnetic ring; 3. a modulation ring assembly; 3-1, magnetic conduction blocks; 3-2, non-magnetic conducting blocks; 4. an outer magnetic ring assembly; 4-1, permanent magnetic ring; 5. an output shaft; 6. a support shaft; 7. a first end cap; 8. a first bearing; 9. a second end cap.
Detailed Description
The invention is further described with reference to the following figures and examples.
Example one
As shown in fig. 1 and 2: a two-stage composite direct-drive motor comprises a winding assembly (1), an inner magnetic ring assembly (2), a modulation ring assembly (3), an outer magnetic ring assembly (4) and an output shaft (5) which are oppositely arranged. The winding assembly (1), the inner magnetic ring assembly (2), the modulation ring assembly (3) and the outer magnetic ring assembly (4) are coaxially sleeved together; the winding assembly (1) is positioned in the inner cavity of the inner magnetic ring assembly (2) and is separated from the inner magnetic ring assembly (2) by an air gap; the inner magnetic ring assembly (2) is positioned in the inner cavity of the modulation ring assembly (3) and is separated from the modulation ring assembly (3) by an air gap; the modulation ring assembly (3) is positioned in the inner cavity of the outer magnetic ring assembly (4) and is separated from the outer magnetic ring assembly (4) by an air gap. The inner magnetic ring assembly (2) is composed of an inner ring permanent magnetic ring (2-1) and an outer ring permanent magnetic ring (2-2). The inner permanent magnet ring (2-1) is formed into a magnet ring with 9 magnetic pole pairs by the N pole and the S pole of 18 permanent magnets which are separated and uniformly arranged in the circumferential direction; the outer permanent magnet ring (2-2) is formed into a magnet ring with the number of pole pairs of 2 by 4 permanent magnets which are arranged evenly in the circumferential direction at intervals between the N pole and the S pole. The modulation ring assembly (3) is formed by arranging magnetic conduction blocks (3-1) and non-magnetic conduction blocks (3-2) at intervals, and the number of the magnetic conduction blocks (3-1) is 25. The permanent magnet ring (4-1) of the outer magnet ring assembly (4) is formed into a magnet ring with the number of pole pairs of 23 by the N poles and the S poles of 46 permanent magnets which are uniformly arranged in the circumferential direction at intervals.
In the structure, the winding assembly (1) is fixed on the first end cover (7) through the support shaft (6), and the inner magnetic ring assembly (2) is installed on the support shaft (6) through the first bearing (8), so that the inner magnetic ring assembly (2) can rotate relative to the winding assembly. The modulation ring assembly (3) is used as a rotor and is connected with the output shaft (5), and the output shaft axially and outwards passes through a second bearing (10) embedded in a second end cover (9) and rotates relative to the second end cover through the second bearing. The outer magnetic ring assembly (4), the first end cover (7) and the second end cover (9) surround to form a shell of the secondary composite direct-drive motor, the outer magnetic ring assembly (4) is located between the first end cover (7) and the second end cover (9), and end faces of two ends of the outer magnetic ring assembly (4) are fixed on the inner wall of the end face of the first end cover (7) and the inner wall of the end face of the second end cover (9) respectively.
Example one
On the basis of the structure, as shown in fig. 1 and 2, the winding assembly (1) is composed of a coil winding (1-1) and an iron core (1-2), the number of pole pairs of the coil winding (1-1) is 2, and the number of salient poles (1-3) on the iron core (1-2) is 11. When the winding assembly (1) is electrified with alternating current, a rotating magnetic field is generated, the rotating magnetic field is modulated by the salient poles (1-3) on the iron core (1-2), and the pole pair number of the generated space harmonic magnetic field is matched with the pole pair number of the inner ring permanent magnet ring (2-1) in the inner ring magnetic ring assembly (2), so that an acting force is generated between the winding assembly (1) and the inner ring magnetic ring assembly (2), and electric energy is converted into kinetic energy to drive the inner ring magnetic ring assembly (2) to rotate; when the inner magnetic ring assembly (2) rotates, the rotating magnetic field of the outer permanent magnetic ring (2-2) is modulated by the magnetic conduction blocks (3-1) on the modulation ring assembly (3) so as to generate a space harmonic magnetic field pole pair number which is matched with the magnetic pole pair number of the permanent magnetic ring (4-1) of the outer magnetic ring assembly (4), so that acting force is generated among the inner magnetic ring assembly (2), the modulation ring assembly (3) and the outer magnetic ring assembly (4), and kinetic energy is output through the output shaft (5).
Example two
On the basis of the structure, as shown in fig. 3 and 4, the winding assembly (1) is composed of coil windings (1-1), common iron cores (1-4) and magnetic adjusting blocks (1-5), the number of pole pairs of the coil windings (1-1) is 2, and the number of the magnetic adjusting blocks (1-5) is 11. When the winding assembly (1) is electrified with alternating current, a rotating magnetic field is generated, the rotating magnetic field is modulated by the magnetic adjusting blocks (1-5), and then the pole pair number of the generated space harmonic magnetic field is matched with the pole pair number of the inner ring permanent magnetic ring (2-1) in the inner ring magnetic ring assembly (2), so that an acting force is generated between the winding assembly (1) and the inner ring magnetic ring assembly (2), and electric energy is converted into kinetic energy to drive the inner ring magnetic ring assembly (2) to rotate; when the inner magnetic ring assembly (2) rotates, the rotating magnetic field of the outer permanent magnetic ring (2-2) is modulated by the magnetic conduction blocks (3-1) on the modulation ring assembly (3) so as to generate a space harmonic magnetic field pole pair number which is matched with the magnetic pole pair number of the permanent magnetic ring (4-1) of the outer magnetic ring assembly (4), so that acting force is generated among the inner magnetic ring assembly (2), the modulation ring assembly (3) and the outer magnetic ring assembly (4), and kinetic energy is output through the output shaft (5).
According to the invention, the winding assembly (1), the inner magnetic ring assembly (2), the modulation ring assembly (3) and the outer magnetic ring assembly (4) are coaxially sleeved together, and through 2 times of magnetic field modulation, on the basis of not increasing the number of pole pairs of coils, the rotating speed of the motor is greatly reduced, and the mechanical structure is simplified. When the winding assembly of the motor is electrified with alternating current, a rotating magnetic field is generated, and for a common permanent magnet motor, when the number of pole pairs of the coil winding is 2, the output rotating speed is 60f/p160 × 50/2r/min 1500 r/min; for the two-stage composite direct-drive motor provided by the invention, a winding assembly (1) of the motor is electrified with a rotating magnetic field generated by alternating current, and after the magnetic field modulation and coupling effects of an inner magnetic ring assembly (2), a modulation ring assembly (3) and an outer magnetic ring assembly (4), the output rotating speed is n-60 f/p1*(p1/p2)*(p4/p5)=60fp4/(p2p5) According to the magnetic pole pair number calculation in the embodiment, the output rotating speed n is 60 × 50 × 2/(9 × 23) ═ 29r/min, the rotating speed is far lower than that of a common permanent magnet motor, and the output of low rotating speed and large torque is realized. In addition, by flexibly setting the number of magnetic pole pairs of each assembly, the two-stage composite direct-drive motor can realize output of various low rotating speeds and large torques, meets the requirements of different low-speed loads, and is suitable for popularization and use.
The above embodiments are only for illustrating the technical idea of the present invention, and the protection scope of the present invention cannot be limited thereby, and any modification made on the basis of the technical scheme according to the technical idea proposed by the present invention falls within the protection scope of the present invention; the technology not related to the invention can be realized by the prior art.

Claims (9)

1. A two-stage composite direct drive motor comprises a winding assembly (1), an inner magnetic ring assembly (2) and a modulation ring assembly which are oppositely arrangedBecome (3), outer magnetic ring assembly (4) and output shaft (5), its characterized in that: the winding assembly (1), the inner magnetic ring assembly (2), the modulation ring assembly (3) and the outer magnetic ring assembly (4) are coaxially sleeved together; the winding assembly (1) is positioned in the inner cavity of the inner magnetic ring assembly (2) and is separated from the inner magnetic ring assembly (2) by an air gap; the inner magnetic ring assembly (2) is positioned in the inner cavity of the modulation ring assembly (3) and is separated from the modulation ring assembly (3) by an air gap; the modulation ring assembly (3) is positioned in the inner cavity of the outer magnetic ring assembly (4) and is separated from the outer magnetic ring assembly (4) by an air gap; the winding assembly (1) is composed of a coil winding (1-1) and an iron core (1-2), and the number of pole pairs of the coil winding (1-1) is p1The number of salient poles (1-3) on the iron core (1-2) is p3(ii) a The inner magnetic ring assembly (2) is composed of an inner ring permanent magnetic ring (2-1) and an outer ring permanent magnetic ring (2-2), and the number of the magnetic pole pairs of the inner ring permanent magnetic ring (2-1) is p2The magnetic pole pair number of the outer ring permanent magnetic ring (2-2) is p4(ii) a Number p of pole pairs of coil winding (1-1)1Salient poles (1-3) p3And the number p of magnetic pole pairs of the inner ring permanent magnet ring (2-1)2Has a relationship of p1+p2=p3(ii) a The modulation ring assembly (3) is formed by arranging magnetic conduction blocks (3-1) and non-magnetic conduction blocks (3-2) at intervals, and the number of the magnetic conduction blocks (3-1) is p6(ii) a The magnetic pole pair number of the permanent magnetic ring (4-1) of the external magnetic ring assembly (4) is p5(ii) a Magnetic pole pair number p of outer ring permanent magnetic ring (2-2)4The number p of the magnetic conduction blocks (3-1) in the modulation ring assembly (3)6And the magnetic pole pair number p of the permanent magnetic ring (4-1) of the outer magnetic ring assembly (4)5The relationship between is p4+p5=p6(ii) a When the winding assembly (1) is electrified with alternating current, a rotating magnetic field is generated, the rotating magnetic field is modulated by the salient poles (1-3) on the iron core (1-2), and the pole pair number of the generated space harmonic magnetic field is matched with the pole pair number of the inner ring permanent magnet ring (2-1) in the inner ring magnetic ring assembly (2), so that an acting force is generated between the winding assembly (1) and the inner ring magnetic ring assembly (2), and electric energy is converted into kinetic energy to drive the inner ring magnetic ring assembly (2) to rotate; when the inner magnetic ring assembly (2) rotates, the rotating magnetic field of the outer permanent magnetic ring (2-2) is modulated by the magnetic conductive blocks (3-1) on the modulation ring assembly (3) so as to generate a space harmonic magnetic field pole pair number which is matched with the magnetic pole pair number of the permanent magnetic ring (4-1) of the outer magnetic ring assembly (4), so that acting force is generated among the inner magnetic ring assembly (2), the modulation ring assembly (3) and the outer magnetic ring assembly (4), and the acting force is generated among the inner magnetic ring assembly (2), the modulation ring assembly (3) and the outer magnetic ring assembly (4)The output shaft (5) outputs the kinetic energy.
2. The two-stage composite direct drive motor according to claim 1, characterized in that: the inner ring permanent magnet ring (2-1) in the inner magnet ring assembly (2) passes through 2p2The N poles and the S poles of the block permanent magnets are uniformly arranged in the circumferential direction at intervals to form a magnetic pole pair number p2The magnetic ring of (2); or through 4p2The block permanent magnets are circumferentially arranged by adopting a Halbach array to form a magnetic pole pair number p2The magnetic ring.
3. The two-stage composite direct drive motor according to claim 1, characterized in that: an outer ring permanent magnet ring (2-2) in the inner magnet ring assembly (2) passes through 2p4The N poles and the S poles of the block permanent magnets are uniformly arranged in the circumferential direction at intervals to form a magnetic pole pair number p4The magnetic ring of (2); or through 4p4The block permanent magnets are circumferentially arranged by adopting a Halbach array to form a magnetic pole pair number p4The magnetic ring.
4. The two-stage composite direct drive motor according to claim 1, characterized in that: the permanent magnet ring (4-1) in the external magnet ring assembly (4) passes through 2p5The N poles and the S poles of the block permanent magnets are uniformly arranged in the circumferential direction at intervals to form a magnetic pole pair number p5The magnetic ring of (2); or through 4p5The block permanent magnets are circumferentially arranged by adopting a Halbach array to form a magnetic pole pair number p5The magnetic ring.
5. The two-stage composite direct drive motor according to claim 1, characterized in that: the winding assembly (1) is fixed on the first end cover (7) through the support shaft (6), and the inner magnetic ring assembly (2) is installed on the support shaft (6) through the first bearing (8), so that the inner magnetic ring assembly (2) can rotate relative to the winding assembly.
6. The two-stage composite direct drive motor according to claim 1, characterized in that: the modulation ring assembly (3) is used as a rotor and is connected with the output shaft (5), and the output shaft axially and outwards passes through a second bearing (10) embedded in a second end cover (9) and rotates relative to the second end cover through the second bearing.
7. The two-stage composite direct drive motor according to claim 1, characterized in that: the outer magnetic ring assembly (4), the first end cover (7) and the second end cover (9) surround to form a shell of the secondary composite direct-drive motor, the outer magnetic ring assembly (4) is located between the first end cover (7) and the second end cover (9), and end faces of two ends of the outer magnetic ring assembly (4) are fixed on the inner wall of the end face of the first end cover (7) and the inner wall of the end face of the second end cover (9) respectively.
8. The two-stage composite direct drive motor according to claim 1, characterized in that: the winding assembly (1) can also be composed of a coil winding (1-1), a common iron core (1-4) and a magnetic adjusting block (1-5), and the number of pole pairs of the coil winding (1-1) is p1The number of the magnetic adjusting blocks (1-5) is p3And the number p of pole pairs of the coil winding (1-1)1The number p of the magnetic adjusting blocks (1-5)3And the number p of magnetic pole pairs of the inner ring permanent magnet ring (2-1)2Has a relationship of p1+p2=p3(ii) a When the winding assembly (1) is electrified with alternating current, a rotating magnetic field is generated, the rotating magnetic field is modulated by the magnetic adjusting blocks (1-5), and then the pole pair number of the generated space harmonic magnetic field is matched with the pole pair number of the inner ring permanent magnetic ring (2-1) in the inner ring magnetic ring assembly (2), so that an acting force is generated between the winding assembly (1) and the inner ring magnetic ring assembly (2), and electric energy is converted into kinetic energy to drive the inner ring magnetic ring assembly (2) to rotate; when the inner magnetic ring assembly (2) rotates, the rotating magnetic field of the outer permanent magnetic ring (2-2) is modulated by the magnetic conduction blocks (3-1) on the modulation ring assembly (3) so as to generate a space harmonic magnetic field pole pair number which is matched with the magnetic pole pair number of the permanent magnetic ring (4-1) of the outer magnetic ring assembly (4), so that acting force is generated among the inner magnetic ring assembly (2), the modulation ring assembly (3) and the outer magnetic ring assembly (4), and kinetic energy is output through the output shaft (5).
9. The winding assembly of claim 8, wherein: the magnetic adjusting blocks (1-5) are uniformly distributed along the circumferential direction of the common iron core (1-4), are tightly attached to the outer circumferential surface of the iron core (1-4), and gaps are reserved between the adjacent magnetic adjusting blocks (1-5).
CN201910166710.4A 2019-03-06 2019-03-06 Two-stage composite direct-drive motor Pending CN111668950A (en)

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Cited By (9)

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CN113949246A (en) * 2021-09-30 2022-01-18 国家电投集团科学技术研究院有限公司 Magnetic gear of axial magnetic flux
CN117277725A (en) * 2022-09-20 2023-12-22 罗灿 Variable block concentric magnetic gear
CN117277726A (en) * 2022-09-20 2023-12-22 罗灿 Variable magnetic concentric magnetic gear
CN117277728A (en) * 2022-09-20 2023-12-22 罗灿 Variable double-output double-magnetic gear
CN117277730A (en) * 2022-09-20 2023-12-22 罗灿 Concentric magnetic gear with equal magnetic adjusting rings
CN117277731A (en) * 2022-09-20 2023-12-22 罗灿 Concentric magnetic gear with new proportioning structure
CN117277727A (en) * 2022-09-20 2023-12-22 罗灿 Synchronous differential magnetic gear
CN117294097A (en) * 2022-09-20 2023-12-26 罗灿 Variable double-rotor magnetic regulating motor
WO2024208897A1 (en) * 2023-04-04 2024-10-10 Ose Magnetic gearbox

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113949246A (en) * 2021-09-30 2022-01-18 国家电投集团科学技术研究院有限公司 Magnetic gear of axial magnetic flux
CN117277725A (en) * 2022-09-20 2023-12-22 罗灿 Variable block concentric magnetic gear
CN117277726A (en) * 2022-09-20 2023-12-22 罗灿 Variable magnetic concentric magnetic gear
CN117277728A (en) * 2022-09-20 2023-12-22 罗灿 Variable double-output double-magnetic gear
CN117277730A (en) * 2022-09-20 2023-12-22 罗灿 Concentric magnetic gear with equal magnetic adjusting rings
CN117277731A (en) * 2022-09-20 2023-12-22 罗灿 Concentric magnetic gear with new proportioning structure
CN117277727A (en) * 2022-09-20 2023-12-22 罗灿 Synchronous differential magnetic gear
CN117294097A (en) * 2022-09-20 2023-12-26 罗灿 Variable double-rotor magnetic regulating motor
WO2024208897A1 (en) * 2023-04-04 2024-10-10 Ose Magnetic gearbox
FR3147611A1 (en) * 2023-04-04 2024-10-11 Ose MAGNETIC GEARBOX

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