CN210693680U - Permanent-magnet direct-drive reaction kettle - Google Patents
Permanent-magnet direct-drive reaction kettle Download PDFInfo
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- CN210693680U CN210693680U CN201921052264.6U CN201921052264U CN210693680U CN 210693680 U CN210693680 U CN 210693680U CN 201921052264 U CN201921052264 U CN 201921052264U CN 210693680 U CN210693680 U CN 210693680U
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Abstract
The utility model discloses a permanent magnet direct-drive reaction kettle, which comprises a winding assembly, a permanent magnet assembly, a support shaft, an isolation cover, a conductor assembly, a stirring shaft, a shell, a first bearing, a second bearing, a third bearing and a kettle body, wherein the permanent magnet assembly comprises an upper magnetic ring, a permanent magnet yoke and a lower magnetic ring; the winding assembly is electrified to generate an induction magnetic field, the magnetic field and the upper magnetic ring act to drive the permanent magnet assembly to rotate, then power is transmitted to the conductor assembly, and the conductor assembly drives the stirring shaft to rotate to complete the stirring process. The utility model discloses a permanent magnetism directly drives reation kettle simple structure, compactness, axial dimension is little, can adapt to high temperature environment, and is efficient, the reliability is high, maintain simply.
Description
Technical Field
The utility model relates to a reation kettle, specifically speaking are novel, simple and easy, reliable integration permanent magnetism directly drives reation kettle.
Background
The reaction kettle is a common device in the chemical industry, and has a plurality of different reaction kettles according to specific requirements, including differences of materials, structures and the like. At present, the common mechanical transmission mode of the reaction kettle is that a motor is connected with a speed reducer and then drives a stirring mechanism, so that the transmission structure is complex, and the stirring mechanism working under flammable, explosive, toxic, corrosive and precious media needs to have high tightness, so that the cost is high and the maintenance workload is large. With the development of magnetic materials, magnetic driving technology is becoming more and more widespread. The magnetic driving technology can realize non-contact torque transmission between a motor and a load and is applied to a reaction kettle. However, the temperature in part of the reaction kettle is high, and the magnetism of the permanent magnet is influenced, so that the static sealing cannot be realized by completely adopting magnetic transmission.
Disclosure of Invention
The utility model aims at the problem that prior art exists, provide a permanent magnetism and directly drive reation kettle, this reation kettle can solve that the permanent magnet among the complicated, sealed requirement of current reation kettle transmission structure, the magnetism drive disk assembly can defect such as demagnetization under high temperature, provide a simple structure, turn into static seal, can be used to the permanent magnetism under the high temperature environment and directly drive reation kettle with the dynamic seal.
The utility model aims at solving through the following technical scheme:
the utility model provides a permanent magnetism directly drives reation kettle, includes winding assembly, permanent magnetism assembly, back shaft, cage, conductor assembly, (mixing) shaft, casing, first bearing, second bearing, third bearing, the cauldron body, its characterized in that: the winding assembly, the permanent magnet assembly, the supporting shaft, the isolation cover and the conductor assembly are arranged in the shell, the supporting shaft is fixed in the shell, the winding assembly is fixed on the supporting shaft, the permanent magnet assembly is connected with the supporting shaft through a first bearing and a second bearing, the permanent magnet assembly comprises an upper magnetic ring, a permanent magnet yoke and a lower magnetic ring, the winding assembly and the upper magnetic ring are concentrically sleeved, the outer circumferential surface of the winding assembly is opposite to the inner circumferential surface of the upper magnetic ring and is separated by an air gap, the conductor assembly and the lower magnetic ring are concentrically arranged and are separated by the isolation cover, the conductor assembly and the isolation cover are separated by the air gap, the lower magnetic ring and the isolation cover are separated by the air gap, the conductor assembly is fixedly connected with a stirring shaft, the stirring shaft is connected with the kettle body through a third bearing, and the permanent magnet direct-; the winding assembly is electrified to generate a rotating induction magnetic field, the induction magnetic field interacts with the upper magnetic ring to drive the permanent magnet assembly to rotate, so that the conductor assembly cuts magnetic lines of force of the lower magnetic ring to generate the induction magnetic field and rotates along with the permanent magnet assembly in the same direction, and the conductor assembly drives the stirring shaft to rotate to complete the stirring process.
The winding assembly comprises an iron core and a winding, wherein the iron core protrudes outwards along the radial direction to form a square block or forms magnetic adjusting blocks in other shapes, and the number of the magnetic adjusting blocks is p3The number of pole pairs of the winding is p1The number of the magnetic pole pairs of the upper magnetic ring is p2Number of magnetic blocks p3Number of pole pairs p of winding1And upper magnetic ring magnetic pole pair number p2The relationship between is p3=p1+p2。
The upper magnetic ring in the permanent magnet 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.
The lower magnetic ring in the permanent magnet 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 conductor assembly comprises a conductor and a conductor yoke, wherein the conductor is made of copper, aluminum or other conductive materials.
The lower magnetic ring in the permanent magnet assembly is of a cylindrical structure and is arranged on the inner circumferential surface of the permanent magnet yoke; the conductor assembly is of a cylindrical structure, the conductor is arranged on the outer circumferential surface of the conductor assembly, and the inner circumferential surface of the lower magnetic ring is opposite to the outer circumferential surface of the conductor.
The lower magnetic ring in the permanent magnet assembly is of a disc-shaped structure and is arranged on the lower end face of the permanent magnet yoke; the conductor assembly is of a disc-shaped structure, the conductor is arranged on the upper end face of the conductor assembly, and the lower end face of the lower magnetic ring is opposite to the upper end face of the conductor.
The isolation cover is made of non-magnetic and non-conductive materials.
Compared with the prior art, the utility model has the following advantages:
the utility model converts the electric energy into kinetic energy and realizes low-speed output by the action of the rotating magnetic field generated by the winding assembly and the upper magnetic ring, finally achieves the function of driving the stirring shaft to rotate by the interaction of the eddy current induction magnetic field of the lower magnetic ring and the conductor assembly, and the upper magnetic ring and the lower magnetic ring form a whole, thereby simplifying the mechanical structure of the transmission part; this permanent magnetism directly drives reation kettle does not have reduction gears for whole drive structure is simpler, compact, and axial dimensions is little, and the conductor assembly who links to each other with the (mixing) shaft can adapt to the high temperature environment, and is efficient, the reliability is high, maintain simply, suitable using widely.
Drawings
FIG. 1 is a schematic structural view of an embodiment of a permanent magnetic direct-drive reaction kettle of the utility model;
FIG. 2 is a schematic structural view of section A-A of FIG. 1;
FIG. 3 is a schematic structural view of section B-B of FIG. 1;
FIG. 4 is a schematic structural view of a second embodiment of the permanent magnetic direct-drive reaction kettle of the present invention;
FIG. 5 is a schematic structural view of section C-C of FIG. 4;
fig. 6 is a schematic structural view of section D-D of fig. 4.
Wherein: 1, winding assembly; 1-1 iron core; 1-2 windings; 1-3 of a magnetic adjusting block; 2, a permanent magnet assembly; 2-1, mounting a magnetic ring; 2-2 permanent magnet yoke iron; 2-3, a lower magnetic ring; 3 supporting the shaft; 4, a shielding case; 5 a conductor assembly; a 5-1 conductor; 5-2 conductor yokes; 6, stirring a shaft; 7, a shell; 8 a first bearing; 9 a second bearing; 10 a third bearing; 11 kettle body.
Detailed Description
The present invention will be further described with reference to the accompanying drawings and examples.
As shown in fig. 1 and 2: a permanent magnet direct-drive reaction kettle comprises a winding assembly 1, a permanent magnet assembly 2, a support shaft 3, an isolation cover 4, a conductor assembly 5, a stirring shaft 6, a shell 7, a first bearing 8, a second bearing 9, a third bearing 10 and a kettle body 11. The winding assembly 1, the permanent magnet assembly 2, the support shaft 3, the isolation cover 4 and the conductor assembly 5 are all arranged in the shell 7, the support shaft 3 is fixed in the shell, and the winding assembly 1 is fixed on the support shaft 3; the winding assembly 1 comprises an iron core 1-1 and a windingIn the group 1-2, the iron core 1-1 protrudes outwards along the radial direction to form a square block to form a magnetic regulating block 1-3; the permanent magnet assembly 2 is connected with the support shaft 3 through a first bearing 8 and a second bearing 9, the permanent magnet assembly 2 comprises an upper magnetic ring 2-1, a permanent magnet yoke 2-2 and a lower magnetic ring 2-3, the winding assembly 1 and the upper magnetic ring 2-1 are concentrically sleeved, the outer circumferential surface of the winding assembly 1 is opposite to the inner circumferential surface of the upper magnetic ring 2-1 and is separated by an air gap, the conductor assembly 5 and the lower magnetic ring 2-3 are concentrically arranged and are separated by an isolation cover 4, the conductor assembly 5 and the isolation cover 4 are separated by the air gap, the lower magnetic ring 2-3 and the isolation cover 4 are separated by the air gap, the conductor assembly 5 is fixedly connected with a stirring shaft 6, and the stirring shaft is connected with a kettle body 11 through a third bearing 10. Specifically, the structural relationship among the windings 1-2, the magnetic adjusting blocks 1-3 and the upper magnetic ring 2-1 is that the number of the magnetic adjusting blocks 1-3 is p3The number of pole pairs of winding 1-2 is p1The number of the magnetic pole pairs of the upper magnetic ring 2-1 is p21-3 number p of magnetic blocks31-2 pole pairs p of windings1And the number p of pole pairs of the upper magnetic ring 2-12The relationship between is p3=p1+p2. In particular to the arrangement of permanent magnets in an upper magnetic ring 2-1 and a lower magnetic ring 2-3 in a permanent magnet assembly 2, the upper magnetic ring 2-1 in the permanent magnet 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 p2Or by 4p2The block permanent magnets are circumferentially arranged by adopting a Halbach array to form a magnetic pole pair number p2The magnetic ring of (2); the lower magnetic ring 2-3 in the permanent magnet 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 p4Or by 4p4The block permanent magnets are circumferentially arranged by adopting a Halbach array to form a magnetic pole pair number p4The magnetic ring. Specifically, the structure and material of the conductor assembly 5 are shown, the conductor assembly 5 comprises a conductor 5-1 and a conductor yoke 5-2, and the conductor 5-1 is made of copper, aluminum or other conductive materials. Specifically, the material of the isolation cover 4 is non-magnetic and non-conductive material for the isolation cover 4.
Example one
On the basis of the structure, as shown in fig. 1 and 3, a lower magnetic ring 2-3 in the permanent magnet assembly is of a cylindrical structure, and the lower magnetic ring 2-3 is arranged on the inner circumferential surface of a permanent magnet yoke 2-2; the conductor assembly 5 is of a cylindrical structure, the conductor 5-1 is arranged on the outer circumferential surface of the conductor assembly 5, and the inner circumferential surface of the lower magnetic ring 2-3 is opposite to the outer circumferential surface of the conductor 5-1.
Example two
On the basis of the structure, as shown in fig. 4, 5 and 6, the lower magnetic ring 2-3 in the permanent magnet assembly 2 is in a disc-shaped structure, and the lower magnetic ring 2-3 is arranged on the lower end face of the permanent magnet yoke 2-2; the conductor assembly 5 is of a disc-shaped structure, the conductor 5-1 is arranged on the upper end face of the conductor assembly 5, and the lower end face of the lower magnetic ring 2-3 is opposite to the upper end face of the conductor 5-1.
The utility model discloses a when permanent magnetism directly drives reation kettle used, winding assembly 1 circular telegram produced rotatory magnetic induction field, and magnetic induction field and last magnetic ring 2-1 interact drive permanent magnet assembly 2 rotatory for conductor assembly 5 cuts down magnetic line of force of magnetic ring 2-3 and produces magnetic induction field and along with permanent magnet assembly 2 equidirectional rotation, and conductor assembly 5 drives the rotatory process of accomplishing the stirring of (mixing) shaft 6.
The utility model converts the electric energy into kinetic energy and realizes low-speed output by the action of the rotating magnetic field generated by the winding assembly and the upper magnetic ring, finally achieves the function of driving the stirring shaft to rotate by the interaction of the eddy current induction magnetic field of the lower magnetic ring and the conductor assembly, and the upper magnetic ring and the lower magnetic ring form a whole, thereby simplifying the mechanical structure of the transmission part; this permanent magnetism directly drives reation kettle does not have reduction gears for whole drive structure is simpler, compact, and axial dimensions is little, and the conductor assembly who links to each other with the (mixing) shaft can adapt to the high temperature environment, and is efficient, the reliability is high, maintain simply, suitable using widely.
The above embodiments are only for explaining 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 provided by the present invention all fall within the protection scope of the present invention; the technology not related to the utility model can be realized by the prior art.
Claims (8)
1. The utility model provides a permanent magnetism directly drives reation kettle, includes winding assembly (1), permanent magnetism assembly (2), back shaft (3), cage (4), conductor assembly (5), (mixing) shaft (6), casing (7), first bearing (8), second bearing (9), third bearing (10), the cauldron body (11), its characterized in that: the winding assembly (1), the permanent magnet assembly (2), the supporting shaft (3), the isolation cover (4) and the conductor assembly (5) are all arranged in the shell (7), the supporting shaft (3) is fixed in the shell, the winding assembly (1) is fixed on the supporting shaft (3), the permanent magnet assembly (2) is connected with the supporting shaft (3) through a first bearing (8) and a second bearing (9), the permanent magnet assembly (2) comprises an upper magnetic ring (2-1), a permanent magnet yoke (2-2) and a lower magnetic ring (2-3), the winding assembly (1) and the upper magnetic ring (2-1) are concentrically sleeved, the outer circumferential surface of the winding assembly (1) is opposite to the inner circumferential surface of the upper magnetic ring (2-1) and is separated by an air gap, the conductor assembly (5) and the lower magnetic ring (2-3) are concentrically arranged and are separated by the isolation cover (4), the conductor assembly (5) is separated from the isolation cover (4) by an air gap, the lower magnetic ring (2-3) is separated from the isolation cover (4) by an air gap, the conductor assembly (5) is fixedly connected with the stirring shaft (6), the stirring shaft is connected with the kettle body (11) through a third bearing (10), and the permanent magnet direct-drive reaction kettle is formed by the arrangement; the winding assembly (1) is electrified to generate a rotating induction magnetic field, the induction magnetic field interacts with the upper magnetic ring (2-1) to drive the permanent magnet assembly (2) to rotate, so that the conductor assembly (5) cuts magnetic lines of force of the lower magnetic ring (2-3) to generate the induction magnetic field and rotates along with the permanent magnet assembly (2) in the same direction, and the conductor assembly (5) drives the stirring shaft (6) to rotate to complete the stirring process.
2. The permanent magnet direct-drive reaction kettle according to claim 1, characterized in that: the winding assembly (1) comprises an iron core (1-1) and windings (1-2), the iron core (1-1) protrudes outwards along the radial direction to form a square block or other shapes to form magnetic adjusting blocks (1-3), and the number of the magnetic adjusting blocks (1-3) is p3The number of pole pairs of the winding (1-2) is p1The number of the magnetic pole pairs of the upper magnetic ring (2-1) is p2Number p of magnetic blocks (1-3)3Number of pole pairs p of winding (1-2)1And the pole pair number p of the upper magnetic ring (2-1)2The relationship between is p3=p1+p2。
3. The permanent magnet direct-drive reaction kettle according to claim 1, characterized in that: the upper magnet in the permanent magnet assembly (2)Ring (2-1) 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.
4. The permanent magnet direct-drive reaction kettle according to claim 1, characterized in that: the lower magnetic ring (2-3) in the permanent magnet 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.
5. The permanent magnet direct-drive reaction kettle according to claim 1, characterized in that: the conductor assembly (5) comprises a conductor (5-1) and a conductor yoke (5-2), and the conductor (5-1) is made of copper, aluminum or other conductive materials.
6. The permanent magnet direct-drive reaction kettle according to claim 1, characterized in that: a lower magnetic ring (2-3) in the permanent magnet assembly (2) is of a cylindrical structure, and the lower magnetic ring (2-3) is arranged on the inner circumferential surface of the permanent magnet yoke (2-2); the conductor assembly (5) is of a cylindrical structure, the conductor (5-1) is arranged on the outer circumferential surface of the conductor assembly (5), and the inner circumferential surface of the lower magnetic ring (2-3) is opposite to the outer circumferential surface of the conductor (5-1).
7. The permanent magnet direct-drive reaction kettle according to claim 1, characterized in that: a lower magnetic ring (2-3) in the permanent magnet assembly (2) is of a disc-shaped structure, and the lower magnetic ring (2-3) is arranged on the lower end face of the permanent magnet yoke (2-2); the conductor assembly (5) is of a disc-shaped structure, the conductor (5-1) is arranged on the upper end face of the conductor assembly (5), and the lower end face of the lower magnetic ring (2-3) is opposite to the upper end face of the conductor (5-1).
8. The permanent magnet direct-drive reaction kettle according to claim 1, characterized in that: the isolation cover (4) is made of non-magnetic and non-conductive materials.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201921052264.6U CN210693680U (en) | 2019-07-08 | 2019-07-08 | Permanent-magnet direct-drive reaction kettle |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201921052264.6U CN210693680U (en) | 2019-07-08 | 2019-07-08 | Permanent-magnet direct-drive reaction kettle |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN210693680U true CN210693680U (en) | 2020-06-05 |
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Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201921052264.6U Active CN210693680U (en) | 2019-07-08 | 2019-07-08 | Permanent-magnet direct-drive reaction kettle |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN210693680U (en) |
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2019
- 2019-07-08 CN CN201921052264.6U patent/CN210693680U/en active Active
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