CN106849610B - Double-output magnetic disk structure of permanent magnet torque converter - Google Patents

Abstract

An input shaft penetrates through a first disk frame disk, the first disk frame disk is arranged on one side of a disk frame outer cylinder, a second disk frame disk is arranged on the other side of the disk frame outer cylinder, the first disk frame disk is connected with a first movable disk, the first output disk is connected with a first output disk output shaft, a second movable disk is sleeved on the outer side of the front end of the first output disk output shaft and connected with the inner wall of the disk frame outer cylinder, a second output disk output hollow shaft is sleeved outside the rear end of the first output disk output shaft, a second output disk is sleeved outside the front end of the second output disk output hollow shaft, a third movable disk is arranged on the front side of the second output disk, a fourth movable disk is arranged on the rear side of the second output disk and connected with the inner wall of the disk frame outer cylinder, and the fourth movable disk is connected with the second disk frame disk. The invention ensures that the gear shifting action is easier to realize, improves the working efficiency of the gear shifting transition working condition of the permanent magnet torque converter and prolongs the service life of equipment.

Description

Double-output magnetic disk structure of permanent magnet torque converter

Technical Field

The invention relates to the field of corollary equipment of a permanent magnet torque converter, in particular to a double-output magnetic disk structure of the permanent magnet torque converter. The method is suitable for the fields of general machinery, household appliances, robots, automobiles, rail vehicles, ships, aircrafts and the like, and is particularly suitable for vehicles.

Background

The permanent magnet torque converter has two working modes, one mode is that the rotating speeds of the disk rack and the output disk are the same, the left and right moving disks synchronously drive the output disk, the output torque is the sum of the magnetic torques applied to the driving disk by the left and right sides, and the output torque works at a certain point between a point a and a point b and outputs stable torque; the other working mode is that the rotating speeds of the magnetic disk frame and the output magnetic disk are different, the magnetic disk frame transmits a power gap to the movable magnetic disks, the phase difference between the left movable magnetic disk and the right movable magnetic disk is 90 degrees, the drive magnetic disk rotates back and forth relative to the magnetic disk frame, the drive magnetic disk transmits power to the output magnetic disk through magnetic field force, the relative rotation angle between the drive magnetic disk and the output magnetic disk is controlled to be about 90 degrees, and the left movable magnetic disk and the right movable magnetic disk work alternately in a torque conversion mode to achieve the purposes of stable output torque and variable size. When the automobile needs to shift gears, the permanent magnet torque converter enters a second working mode, the gear-up is selected as an example for convenience of explanation, and the gear-down condition is similar. After the upshift signal is obtained, the disk rack releases the right drive disk, only the left drive disk transmits power at the moment, the right drive disk rotates by about 90 degrees relative to the disk rack along with the output disk, then the left and right disks rotate alternately and reciprocally relative to the output disk, and the rotating angle and speed law of the right and left drive disks have strict limits.

In the prior art, the gear shifting time of the DSG automatic transmission is 200ms, the requirement is high, the efficiency of the transition state stage of the whole permanent magnet torque converter can be changed when the gear is shifted up or shifted down, so that the working efficiency of the whole permanent magnet torque converter is influenced, and when the gear is shifted off or engaged, the torque of a connecting mechanism of the existing equipment for disconnection or engagement is often large, so that the service life of the connecting mechanism is seriously influenced.

Disclosure of Invention

In order to solve the existing problems, the invention provides a dual-output disk structure of a permanent magnet torque converter, wherein a first output disk output shaft is connected with odd gears of a transmission, a second output disk output hollow shaft is connected with even gears of the transmission, 3 moving disks participate in power transmission during gear shifting, so that the transmission torque of each moving disk is reduced, an engine speed regulator can be better introduced, the gear shifting action is easier to realize, the gear shifting transition working condition working efficiency of the permanent magnet torque converter is improved, and the service life of equipment is prolonged The first control rod of the disc penetrates out of the hole, the first movable disc corresponds to the first output disc, the first output disc is connected with the first output disc output shaft, the outer side of the front end of the first output disc output shaft is sleeved with a second movable disc, the second movable disc is connected with the inner wall of the outer drum of the disc frame through a second movable disc and disc frame connecting structure, one end of a second movable disc control connecting rod is connected with the outer wall of the disc frame connecting structure, the other end of the second movable disc control connecting rod penetrates out of the second control rod protruding out of the hole of the outer wall of the front end of the outer drum of the disc frame, the rear end of the first output disc output shaft is sleeved with a second output disc hollow shaft, and the front end of the second output disc hollow shaft is sleeved with a second output disc, the front side of the second output disk is provided with a third movable disk, the rear side of the second output disk is provided with a fourth movable disk, the third movable disk is connected with the inner wall of the disk rack outer cylinder through a third movable disk and disk rack connecting structure, one end of a third movable disk control connecting rod is connected with the third movable disk and disk rack connecting structure, the other end of the third movable disk control connecting rod penetrates out of a third control rod extending hole in the outer wall of the rear end of the disk rack outer cylinder, the fourth movable disk is connected with the disk rack second disk through a fourth movable disk and disk rack connecting structure, one end of a fourth movable disk control connecting rod is connected with the fourth movable disk and disk rack connecting structure, and the other end of the fourth movable disk control connecting rod penetrates out of a fourth control rod extending hole in the disk rack second disk.

According to the further improvement of the invention, the first output magnetic disk and the second output magnetic disk are internally provided with a main fan-shaped magnet, a superposed fan-shaped magnet and an auxiliary fan-shaped magnet, the N pole and the S pole of the fan-shaped magnet in the first movable magnetic disk or the third movable magnetic disk are opposite to the N pole and the S pole of the fan-shaped magnet in the second movable magnetic disk or the fourth movable magnetic disk along the axial direction, and the polarities of the magnets in the movable magnetic disks at two sides are opposite, so that the speed of the engine is regulated during downshift, and better gear shifting quality and transmission efficiency are obtained.

In a further improvement of the invention, the included angles between the sector magnets in the first movable magnetic disk and the third movable magnetic disk and the sector magnets in the second movable magnetic disk and the fourth movable magnetic disk are 30-50 degrees, and the optimal operation effect is achieved through the limitation of the included angles.

In the further improvement of the invention, bearings are sleeved on the shafts between the first movable magnetic disc and the input shaft, between the second movable magnetic disc and the first output magnetic disc output shaft, and between the third movable magnetic disc, the fourth movable magnetic disc, the magnetic disc frame, the second disc and the second output magnetic disc output hollow shaft, and the friction coefficient is reduced by arranging the bearings.

The invention provides a double-output magnetic disk structure of a permanent magnet torque converter, which has the following specific advantages:

1. when the connection structure of the second movable magnetic disk and the disk rack disconnects the power transmission between the second movable magnetic disk and the disk rack outer cylinder, except that the transmission torque is smaller, the rotation speed difference between the first output magnetic disk and the second movable magnetic disk is smaller, so that the control time is longer, and the requirement that the gear shifting time of the conventional DSG automatic transmission is 200ms is not met;

2. the polarity of the magnetic field is opposite when the sector magnets in the first movable magnetic disc or the third movable magnetic disc and the sector magnets in the second movable magnetic disc or the fourth movable magnetic disc are arranged, when the gear is shifted up or shifted down, the movable magnetic disc of the gear needing to be disconnected can still transmit power in the forward direction in a transition state, and only the mechanical property is soft, so that a part of circulating power possibly exists, and the efficiency in the transition state stage is basically unchanged;

3. when the gear is disengaged and engaged, the transmission torque of the connecting mechanism which performs disconnection or engagement action is reduced to about 1/3 of the whole transmission torque, even smaller, so that the service life of the connecting mechanism is longer;

4. the device can ensure that the power is not interrupted and is relatively stable when the gear is shifted up and down.

Drawings

FIG. 1 is a schematic view of the present invention;

FIG. 2 is a schematic view of a portion of a disk holder of the present invention;

FIG. 3 is a schematic view of a disk holder disk of the present invention;

FIG. 4 is a schematic diagram of an output disk of the present invention;

FIG. 5 is a schematic view of a left acting disk of the present invention;

FIG. 6 is a schematic view of the right-hand disk of the present invention;

FIG. 7 is a graph of the magnetic torque versus the relative rotation angle between the moving and output discs as actually measured by the present invention;

description of the drawings:

1. an input shaft; 2. a first moving disk control link; 3. a disk frame first disk; 4. the first movable magnetic disk and the magnetic disk frame are connected; 5. a first moving disk; 6. the second moving magnetic disk control connecting rod; 7. a first output disk; 8. a third moving magnetic disk control connecting rod; 9. a disk rack outer cylinder; 10. the third moving magnetic disk and the disk rack connecting structure; 11. a third movable magnetic disk; 12. a second output disk; 13. a fourth movable magnetic disk; 14. the fourth movable magnetic disk and the disk rack connecting structure; 15. a disk rack second disk; 16. a fourth moving magnetic disk control connecting rod; 17. a first output disk output shaft; 18. a second output disk output hollow shaft; 19. a bearing; 20. the second movable magnetic disk and the disk rack connecting structure; 21. a second moving disk; 22. a main sector magnet; 23. superposing the sector magnets; 24. a sub fan-shaped magnet; 25. a sector magnet in the first or third moving disk; 26. a sector magnet in the second or fourth moving disk; 27. the first control rod extends out of the hole; 28. the second control rod extends out of the hole; 29. a third control rod extends out of the hole; 30. the fourth control rod extends out of the hole.

Detailed Description

The invention is described in further detail below with reference to the following detailed description and accompanying drawings:

the invention provides a double-output magnetic disc structure of a permanent magnet torque converter, wherein a first output magnetic disc output shaft is connected with an odd gear of a transmission, a second output magnetic disc output hollow shaft is connected with an even gear of the transmission, and 3 moving magnetic discs participate in power transmission during gear shifting, so that the transmission torque of each moving magnetic disc is reduced, the rotation speed of an engine can be better introduced for regulation, the gear shifting action is easier to realize, the gear shifting transition working condition working efficiency of the permanent magnet torque converter is improved, and the service life of equipment is prolonged.

As an embodiment of the invention, the invention provides a double-output disk structure of a permanent magnet torque converter, which comprises an input shaft 1, a first moving disk control connecting rod 2, a disk frame first disk 3, a first moving disk and disk frame connecting structure 4, a first moving disk 5, a second moving disk control connecting rod 6, a first output disk 7, a third moving disk control connecting rod 8, a disk frame outer cylinder 9, a third moving disk and disk frame connecting structure 10, a third moving disk 11, a second output disk 12, a fourth moving disk 13, a fourth moving disk and disk frame connecting structure 14, a disk frame second disk 15, a fourth moving disk control connecting rod 16, a first output disk output shaft 17, a second output disk output hollow shaft 18, a second moving disk and disk frame connecting structure 20, a second moving disk 21, a main fan-shaped magnet 22, a superimposed fan-shaped magnet 23, an auxiliary fan-shaped magnet 24, a fan-shaped magnet 25 in the first moving disk or the third moving disk and a fan-shaped magnet 26 in the second moving disk or the fourth moving disk, the input shaft 1 penetrates through a first disk rack disc 3, the first disk rack disc 3 is arranged on one side of a disk rack outer cylinder 9, a second disk rack disc 15 is arranged on the other side of the disk rack outer cylinder 9, the first disk rack disc 3 is connected with a first movable disk 5 through a first movable disk and disk rack connecting structure 4, a first movable disk control connecting rod 2 arranged on one side of the first movable disk and disk rack connecting structure 4 penetrates out of a first control rod extending hole 27 of the first disk rack disc 3, the first movable disk 5 corresponds to a first output disk 7, the first output disk 7 is connected with a first output disk output shaft 17, a second movable disk 21 is sleeved on the outer side of the front end of the first output disk output shaft 17, the second moving disk 21 is connected with the inner wall of the disk holder outer cylinder 9 through a second moving disk and disk holder connecting structure 20, one end of the second moving disk control connecting rod 6 is connected with the outer wall of the disk holder connecting structure 20, the other end of the second moving disk control connecting rod 6 penetrates out of a second control rod extending hole 28 in the outer wall of the front end of the disk holder outer cylinder 9, a second output disk output hollow shaft 18 is sleeved outside the rear end of the first output disk output shaft 17, a second output disk 12 is sleeved outside the front end of the second output disk output hollow shaft 18, a third moving disk 11 is arranged on the front side of the second output disk 12, a fourth moving disk 13 is arranged on the rear side of the second output disk 12, the third moving disk 11 is connected with the inner wall of the disk holder outer cylinder 9 through a third moving disk and disk holder connecting structure 10, one end of the third moving disk control connecting rod 8 is connected with the third moving disk holder connecting structure 10, the other end of the third moving disk control connecting rod 8 penetrates out of a third control rod extending hole 29 in the outer wall of the disk holder connecting structure 9, the fourth moving disk holder connecting rod 14 is connected with a fourth moving disk holder connecting rod 15, and one end of the fourth moving disk holder connecting rod 16 is connected with a fourth moving disk holder connecting rod 15, and the fourth moving disk control rod 16.

As a specific embodiment of the present invention, the present invention provides a dual-output disk structure of a permanent magnet torque converter as shown in fig. 1-4, which comprises an input shaft 1, a first moving disk control connecting rod 2, a disk frame first disk 3, a first moving disk and disk frame connecting structure 4, a first moving disk 5, a second moving disk control connecting rod 6, a first output disk 7, a third moving disk control connecting rod 8, a disk frame outer cylinder 9, a third moving disk and disk frame connecting structure 10, a third moving disk 11, a second output disk 12, a fourth moving disk 13, a fourth moving disk and disk frame connecting structure 14, a disk frame second disk 15, a fourth moving disk control connecting rod 16, a first output disk output shaft 17, a second output disk output hollow shaft 18, a second moving disk and disk frame connecting structure 20, a second moving disk 21, a main sector magnet 22, a superimposed sector magnet 23, an auxiliary sector magnet 24, a sector magnet 25 in the first moving disk or the third moving disk, and a sector magnet 26 in the second moving disk or the fourth moving disk, the input shaft 1 penetrates through a first disk rack disc 3, the first disk rack disc 3 is arranged on one side of a disk rack outer cylinder 9, a second disk rack disc 15 is arranged on the other side of the disk rack outer cylinder 9, the first disk rack disc 3 is connected with a first movable disk 5 through a first movable disk and disk rack connecting structure 4, a first movable disk control connecting rod 2 arranged on one side of the first movable disk and disk rack connecting structure 4 penetrates out of a first control rod extending hole 27 of the first disk rack disc 3, the first movable disk 5 corresponds to a first output disk 7, the first output disk 7 is connected with a first output disk output shaft 17, a second movable disk 21 is sleeved on the outer side of the front end of the first output disk output shaft 17, the second moving disk 21 is connected to the inner wall of the outer disk holder 9 through a second moving disk and disk holder connecting structure 20, one end of the second moving disk control connecting rod 6 is connected to the outer wall of the disk holder connecting structure 20, the other end of the second moving disk control connecting rod 6 passes through a second control rod extending hole 28 in the outer wall of the front end of the outer disk holder 9, a second output disk output hollow shaft 18 is sleeved outside the rear end of the first output disk output shaft 17, a second output disk 12 is sleeved outside the front end of the second output disk output hollow shaft 18, a third moving disk 11 is arranged on the front side of the second output disk 12, a fourth moving disk 13 is arranged on the rear side of the second output disk 12, the third moving disk 11 is connected to the inner wall of the outer disk holder 9 through a third moving disk and disk holder connecting structure 10, one end of the third moving disk control connecting rod 8 is connected to the disk holder connecting structure 10 through a third moving disk holder connecting structure 10, one end of the third moving disk control connecting rod extends through a fan-shaped magnet outlet hole 29 in the outer wall of the disk holder connecting structure 10, the fourth moving disk holder connecting rod 8 and a fan-shaped magnet outlet hole 15 of the second moving disk holder connecting rod 14, and a fan-shaped magnet 14 of the second moving disk holder connecting rod 14 are connected to the fourth moving disk holder, and a fan-shaped magnet output disk holder connecting rod 15, and a fan-shaped magnet of the fourth moving disk 6, another end of the second moving disk holder connecting rod 14 are connected to the fourth moving disk holder connecting rod 14, and a fan-shaped magnet output disk holder connecting rod 15, and a fan-shaped magnet output disk 6, and a fan-shaped magnet output fan-shaped magnet 23 of the second moving disk holder connecting rod 15, and a fan-shaped magnet output disk holder connecting rod 15 of the second moving disk holder connecting rod 14 are arranged in the second moving disk holder connecting rod 23, and a fan-shaped magnet output disk holder connecting rod 23, and a fan-shaped magnet 23 of the second moving disk holder connecting rod 23, the magnets in the moving magnetic disks on the two sides are arranged in opposite polarities, so that the speed of the engine is adjusted during downshift, better shift quality can be obtained, and the transmission efficiency is improved, the included angles between the sector magnets 25 in the first moving magnetic disk and the third moving magnetic disk and the sector magnets 26 in the second moving magnetic disk and the fourth moving magnetic disk are 30-50 degrees, the optimal operation effect is achieved through the limitation of the included angles, the bearings 19 are sleeved on the shafts between the first moving magnetic disk 5 and the input shaft 1, between the second moving magnetic disk 21 and the first output magnetic disk output shaft 17, and between the third moving magnetic disk 11, the fourth moving magnetic disk 13, the magnetic disk rack second disk 15 and the second output magnetic disk output hollow shaft 18, and the friction coefficient is reduced through the arrangement of the bearings.

The working principle of the invention is as follows: the first output disk output shaft 17 is connected with the odd gears of the transmission, and the second output disk output hollow shaft 18 is connected with the even gears of the transmission, which can be interchanged. Taking a 1-gear shift and a 2-gear shift as an example, assuming that the first output disk output shaft 17 is connected with the 1 gear, the second output disk output hollow shaft 18 is connected with the 2 gear, firstly, the 2 gear is engaged, so that the third movable disk and disk rack connecting structure 10 transmits power, and the fourth movable disk and disk rack connecting structure 14 does not transmit power, the torque value transmitted by the first movable disk 5 and the second movable disk 21 is reduced to 2/3 of the original value, the relative rotation angle between the first movable disk 5, the second movable disk 21 and the first output disk 7 is changed to be in a b section, the torque transmitted by the second movable disk 21 is rapidly reduced, at the moment, the second movable disk control connecting rod 6 is operated to easily disconnect the power transmission between the second movable disk 21 and the disk rack connecting structure 20, then the first movable disk 5 and the third movable disk 11 are in a slip difference working condition to transmit power, the power is continuously transmitted during the shift, the torque is not greatly reduced, the torque has a certain value, when the third movable disk 11 and the second output disk rack connecting structure 12 approach, the fourth output disk drive connecting structure 14 transmits torque, and the torque transmission is completed when the torque transmission is completed. The downshifting action is similar to the action of the second moving-disk control connecting rod 6, the action state of the first moving disk is exchanged with the action state of the first moving disk and disk rack connecting structure 4, the action state of the third moving disk and disk rack connecting structure 10 is exchanged with the action state of the fourth moving disk and disk rack connecting structure 14.

Fig. 7 shows the law of the relative rotation angle between the magnetic torque and the moving disk and the output disk, where there is a recessed portion in the middle, and when shifting gears, since the disk pair to be engaged acts on the moving disk on one side, the torque transmitted by the original driving disk pair will drop, so that the relative rotation angle will change, and at this time, at an appropriate time, the original driving disk pair can disconnect the moving disk on one side at the recessed portion (where the magnetic torque is smaller), thereby reducing the difficulty of disconnecting the gears. When the gear shifting is finished, the magnetic disk needing to be geared acts on the movable magnetic disk on the other side, and the original transmission magnetic disk is easy to break off from the movable magnetic disk on the other side in the concave position.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way, but any modifications or equivalent variations made according to the technical spirit of the present invention are within the scope of the present invention as claimed.

Claims (1)

1. The utility model provides a dual output disk structure of permanent magnet torque converter, including input shaft (1), first moving disk control connecting rod (2), disk rack first disc (3), first moving disk and disk rack connection structure (4), first moving disk (5), second moving disk control connecting rod (6), first output disk (7), third moving disk control connecting rod (8), disk rack urceolus (9), third moving disk and disk rack connection structure (10), third moving disk (11), second output disk (12), fourth moving disk (13), fourth moving disk and disk rack connection structure (14), disk rack second disc (15), fourth moving disk control connecting rod (16), first output disk output shaft (17), second output disk output hollow shaft (18), second moving disk and disk rack connection structure (20), second moving disk (21), main fan-shaped magnet (22), stack fan-shaped magnet (23), vice fan-shaped magnet (24), fan-shaped magnet in first moving disk or third moving disk (25) and fourth moving disk (26), its characterized in that: the input shaft (1) penetrates through a first disk rack disc (3), the first disk rack disc (3) is arranged on one side of a disk rack outer cylinder (9), a second disk rack disc (15) is arranged on the other side of the disk rack outer cylinder (9), the first disk rack disc (3) is connected with a first moving disk (5) through a first moving disk and disk rack connecting structure (4), a first moving disk control connecting rod (2) penetrates out of a first control rod extending hole (27) of the first disk rack disc (3) through a first moving disk, the first moving disk (5) corresponds to a first output disk (7), the first output disk (7) is connected with a first output disk output shaft (17), a second moving disk (21) is sleeved outside the front end of the first output disk output shaft (17), the second moving disk (21) penetrates out of a second disk rack disc output shaft (6) through a second moving disk and disk rack connecting structure (20) and is connected with the inner wall of the disk rack outer cylinder (9), the second moving disk control connecting rod (6) penetrates out of the second disk rack disc output shaft (6), and the second moving disk output shaft (6) is connected with a second output disk control hollow shaft (6), a second output disk (12) is sleeved outside the front end of the second output disk output hollow shaft (18), a third movable disk (11) is arranged on the front side of the second output disk (12), a fourth movable disk (13) is arranged on the rear side of the second output disk (12), the third movable disk (11) is connected with the inner wall of the disk rack outer cylinder (9) through a third movable disk and disk rack connecting structure (10), one end of a third movable disk control connecting rod (8) is connected with the third movable disk and disk rack connecting structure (10), the other end of the third movable disk control connecting rod (8) penetrates out of a third control rod extending hole (29) in the outer wall of the rear end of the disk rack (9), the fourth movable disk (13) is connected with a disk rack second disk (15) through a fourth movable disk and disk rack connecting structure (14), one end of a fourth movable disk control connecting rod (16) is connected with the fourth movable disk and disk rack connecting structure (14), and the other end of the fourth movable disk control connecting rod (16) penetrates out of a second disk rack outer cylinder (30);

a main sector magnet (22), a superposed sector magnet (23) and an auxiliary sector magnet (24) are arranged in the first output magnetic disk (7) and the second output magnetic disk (12), and the N pole and the S pole of the sector magnet (25) in the first movable magnetic disk or the third movable magnetic disk are opposite to the N pole and the S pole of the sector magnet (26) in the second movable magnetic disk or the fourth movable magnetic disk along the axial direction;

the included angle between the sector magnet (25) in the first movable magnetic disk or the third movable magnetic disk and the sector magnet (26) in the second movable magnetic disk and the fourth movable magnetic disk is 30-50 degrees;

and a bearing (19) is sleeved between the first movable magnetic disk (5) and the input shaft (1), and three bearings (19) are sleeved on the shaft between the second movable magnetic disk (21) and the first output magnetic disk output shaft (17), wherein the bearing (19) and the third movable magnetic disk (11), the fourth movable magnetic disk (13), the magnetic disk rack second magnetic disk (15) and the second output magnetic disk output hollow shaft (18) are sleeved between the second movable magnetic disk and the input shaft.

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