CN215257687U - Magnetorheological fluid-based differential with self-locking function - Google Patents

Abstract

The utility model relates to a differential mechanism that has self-locking function based on magnetorheological suspensions, constitute by differential mechanism group and magnetorheological suspensions group, differential mechanism group includes the differential mechanism left and right sides shell, half axle gear, planetary gear and final drive driven gear, the final drive driven gear in differential mechanism left side shell and the magnetorheological suspensions group is fixed with the magnetorheological suspensions shell, the sleeve endotheca of shell has half axle gear and rather than the planetary gear who meshes about the differential mechanism, magnetorheological suspensions group, including the magnetorheological suspensions shell, magnetorheological suspensions grid, coil, brush and brush box, be equipped with the magnetorheological suspensions grid in the magnetorheological suspensions shell, its outside winding lead wire and the coil that the brush is connected, the circular telegram is connected to brush and brush box, the electric current passes through brush box and transmits to the lead wire through the brush. The utility model discloses high loss, the adhesion form differential mechanism lock of having avoided friction form differential mechanism lock rely on great shortcoming to ambient temperature condition, and can control differential mechanism's interior friction moment's size according to actual need, widened differential mechanism's use operating mode.

Description

Magnetorheological fluid-based differential with self-locking function

Technical Field

The utility model belongs to the technical field of vehicle transmission system's differential mechanism, concretely relates to differential mechanism with self-locking function based on magnetorheological suspensions.

Background

When the automobile is bent or runs on a road surface with different left and right heights, the left and right driving wheels of the automobile run on different paths, the driving wheels need a differential mechanism to perform differential speed, and simultaneously transmit torque, so that the driving wheels on two sides are ensured to roll purely, the abrasion of tires is reduced, the transmission efficiency is improved, and the service life of parts is prolonged. The ordinary planetary gear type differential performs differential speed by a torque difference between the left and right wheels, and in some special cases, the differential needs to be self-locked to break away from a predicament. The commonly used self-locking principle is: the half axle gear can not rotate relative to the differential case by locking the half axle gear, thereby achieving the purpose of differential.

The conventional differential with a limited slip function is usually a viscous coupling type differential and a mechanical friction plate type differential, wherein the viscous coupling type differential utilizes the viscosity of liquid or the shearing action of an oil film to realize self-locking, the mechanical performance of the differential is greatly influenced by the temperature of oil liquid, the mechanical friction plate type differential utilizes the friction force generated when the friction plates rotate in a relative slip mode to realize self-locking, a large amount of abrasion and friction heat are generated in the working process of the mechanical friction plate type differential, the abrasion and the friction heat can influence the working stability of the differential, the self-locking torque of the differential is fixed, the size of the self-locking torque can not be intelligently adjusted according to the environment and the self-locking requirements, and the intelligent differential is not provided.

Disclosure of Invention

The utility model aims at providing a differential mechanism with self-locking function based on magnetorheological suspensions to solve the problem that differential mechanism exists and excessively relies on external environment temperature, wearing and tearing height and can not adjust differential moment among the prior art.

The utility model aims at realizing through the following technical scheme:

a differential mechanism with a self-locking function based on magnetorheological fluid is composed of a differential mechanism group and a magnetorheological group;

the differential group mainly comprises a differential left shell 25, a differential right shell 2, a half axle gear 5, a planetary gear 1 and a main reducer driven gear 9; the differential left shell 25 comprises a flange plate and a sleeve positioned on the right side of the flange plate, and the inner end and the outer end of the flange plate are respectively fixed with the driven gear 9 of the main speed reducer and the magnetic current transformer shell 22 in the magnetic current transformer set; the differential right shell 2 comprises a sleeve, and a half shaft gear 5 and a planetary gear 1 meshed with the half shaft gear are sleeved in the sleeve of the differential left shell 25 and the sleeve of the differential right shell 2; the differential further comprises a half shaft 3, a spline half shaft 16 and a cross shaft 26, wherein the half shaft 3 penetrates through the right differential shell 2 to be matched with the inner half shaft gear 5; the right side of the spline half shaft 16 is matched with a half shaft gear 5 in a left differential shell 25; the two planetary gears 1 are sleeved on a cross shaft 26, and the cross shaft 26 is sleeved in four circular through holes formed when the differential left shell 25 and the differential right shell 2 are connected;

the magnetorheological device group also comprises two magnetorheological device shells 19, a magnetorheological device grid 15, a coil 21, an electric brush 20 and an electric brush box 12; the two magnetorheological device shells 19 are fixed in the magnetorheological device shell 22 and can be spliced into six circular plate-shaped gratings and an inner cavity, the magnetorheological device gratings 15 matched with the spline half shaft 16 are arranged in the magnetorheological device shells, bearings 17 are arranged on two sides of the magnetorheological device shells, and the left bearing 17 and the right bearing 17 are respectively connected with a shoulder on the left side of the magnetorheological device shell 22 and a flange neck of a differential left shell 25; the magnetorheological fluid is characterized in that a coil 21 is wound outside the magnetorheological device shell 19, a lead of the coil 21 is connected with an electric brush 20 through a small through hole in the side wall of the magnetorheological device shell 22, the electric brush 20 is connected with the electric brush box 12 and electrified, the electric current is transmitted to the lead through the electric brush box 12 and the electric brush 20, the lead is electrified to generate a magnetic field, and the magnetorheological fluid is changed into a solid-like body from liquid under the action of the magnetic field.

Further, the ring flange and the sleeve integrated into one piece of differential mechanism left side shell 25 open on the ring flange eight be used for connecting main reducer driven gear 9 and the circular through-hole of magnetic current transformer shell 22, and it has four circular through-holes that are used for connecting differential mechanism right side shell 2 to open on the sleeve, and the sleeve is inside to be equipped with spherical annular, and differential mechanism left side shell 25 is connected with main reducer driven gear 9, magnetic current transformer shell 22 and differential mechanism right side shell 2 through bolt and nut.

Furthermore, 2 shells of differential mechanism right side shell are opened four and are used for connecting the circular through-hole of differential mechanism left side shell 25, are equipped with hollow out construction and spherical annular in the sleeve, and 2 flanks of differential mechanism right side shell are equipped with the stiffening rib, and 2 rightmost sides of differential mechanism right side shell are equipped with a circular bead for install the differential mechanism bearing.

Further, the half shaft 3 passes through the right differential case 2 and is matched with the half shaft gear 5 through splines, the spline at the rightmost side of the spline half shaft 16 is matched with the half shaft gear 5, the spline in the middle of the spline half shaft is matched with the spline of the magnetic current transformer grating 15, and the half shaft gear 5 is sleeved on the half shaft 3 and the spline half shaft 16 through the splines and is sleeved in the circular plane of the right differential case 2 and the left differential case 25.

Further, the cross shaft 26 is a cross-shaped optical axis, and the planet gear 1 is sleeved on the cross shaft 26 through an inner circular hole.

Furthermore, the magnetic current transformer shell 22 is of a cylindrical structure, eight circular through grooves used for connecting the differential left shell 25 and the main speed reducer driven gear 9 are formed in the outermost cylinder wall of the magnetic current transformer shell 22, four circular through holes used for fixing the magnetic current transformer shell 19 are formed in the middle of the outermost cylinder wall of the magnetic current transformer shell 22, and a shoulder is formed in the leftmost side of the magnetic current transformer shell 22 and used for mounting a differential bearing.

Further, the two magneto rheological shells 19 are of a symmetrical cylindrical structure, the two magneto rheological shells 19 are fixed with bolts and nuts through holes of four square bosses on the outer side, the two magneto rheological shells 19 are fixed in a cylindrical inner cavity of the magneto rheological shell 22 through a threaded hole on the leftmost side, annular concave platforms formed by splicing the left side and the right side of the two magneto rheological shells are used for accommodating the fixed bearing 17, sealing rings I18 are respectively installed on two sides of the inner cavities of the two magneto rheological shells 19, and a sealing ring II 23 is further installed on the right side of the magneto rheological shell 19.

Further, the magnetic current transformer grating 15 is of a disc-shaped structure, splines in the magnetic current transformer grating 15 are matched with splines of the spline half shaft 16, seven circular plate-mounted gratings are arranged outside the magnetic current transformer grating in a staggered mode, the gratings are parallelly staggered with six circular plate-shaped gratings of the magnetic current transformer shell 19, magnetic current transformer liquid is changed into a solid-like body under the action of a magnetic field formed by electrifying the coil 21, resistance torque is formed between the magnetic current transformer grating 15 and the magnetic current transformer shell 19, and the resistance torque is transmitted to the half shaft gear 5 through the spline half shaft 16.

Further, the magnetic flow modulator further comprises an annular inner sealing ring 11 and an annular outer sealing ring 10, wherein a cylindrical part in the middle of the inner sealing ring 11 is sleeved on the outer side of the magnetic flow modulator shell 22, the cylindrical part is provided with a through hole corresponding to the magnetic flow modulator shell 22, and annular parts on two sides of the inner sealing ring 11 are matched with the outer sealing ring 10 to form a sealing cavity; the cylindrical part and the brush box in the middle of the outer sealing ring 10 are installed on the inner side of the axle housing, the annular parts on the two sides are sleeved with the annular parts on the two sides of the inner sealing ring 11, and the outer sealing ring 10 can rotate relative to the inner sealing ring 11.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses differential mechanism with self-locking function based on magnetorheological suspensions controls magnetorheological suspensions's mechanical state through the size of control coil internal current, and then controls differential mechanism's working method, has avoided high loss shortcoming, the adhesion form differential mechanism lock of friction form differential mechanism lock to rely on great shortcoming to ambient temperature condition, and can control differential mechanism's internal friction moment's size according to actual need, has widened differential mechanism's use operating mode.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural view of a differential mechanism with a self-locking function based on magnetorheological fluid;

2-3 are perspective views of the planet gear shaft;

FIGS. 4-6 are isometric views of the right housing of the differential;

FIGS. 7-8 are perspective views of the axle shaft gear;

9-10 outer seal ring structure diagrams;

FIG. 11 is a schematic structural view of an inner seal ring;

FIG. 12 is a schematic view of a brush box construction;

13-15 are isometric views of a magnetorheological grid;

FIG. 16 is a schematic view of a splined axle shaft configuration;

FIGS. 17-19 are isometric views of a magnetorheological housing;

FIGS. 20-22 are isometric views of a magnetorheological device housing;

23-25 are isometric views of the left housing of the differential;

FIG. 26 is a cross-shaft schematic;

FIGS. 27-32 are schematic views of the assembly of a magnetorheological housing and a magnetorheological grille.

In the drawing, 1, a planetary gear 2, a differential right shell 3, a half shaft 4, a half shaft gasket 5, a half shaft gear 6, a planetary gear gasket 7, a nut I8, an elastic washer 9, a main speed reducer driven gear 10, an outer sealing ring 11, an inner sealing ring 12, an electric brush box 13, a bolt I14, a bolt 15, a magnetic current transformer grating 16, a spline half shaft 17, a bearing 18, a sealing ring I19, a magnetic current transformer shell 20, an electric brush 21, a coil 22, a magnetic current transformer shell 23, a sealing ring II 24, a bolt II 25, a differential left shell 26, a cross shaft 27, an elastic washer 28 and a nut II.

Detailed Description

The invention will be further described with reference to the following examples:

the present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures. Meanwhile, in the description of the present invention, the terms "first", "second", and the like are used only for distinguishing the description, and are not to be construed as indicating or implying relative importance.

As shown in fig. 1-32, the differential mechanism with self-locking function based on magnetorheological fluid of the present invention is composed of a differential set and a magnetorheological set.

The differential set mainly comprises a differential left shell 25, a differential right shell 2, a half axle gear 5, a planetary gear 1 and a main reducer driven gear 9. The differential group plays roles of inter-axle differential, speed reduction and torque increase, torque direction change and the like.

Wherein, the differential left shell 25 is a mounting base body of the internal gear of the differential. The left side of the differential left shell 25 is of a flange structure, and the inner side of the neck of the differential left shell is connected with a bearing 17 positioned on the right side of a magnetic flow changer grid 15 in a magnetic flow changer set to limit the differential left shell. Eight circular through holes are formed in a flange plate of the flange, the eight through holes correspond to the through holes in the main speed reducer driven gear 9 and the magnetic current transformer shell 22 respectively, and the main speed reducer driven gear 9 and the magnetic current transformer shell 22 are connected with the fixed differential left shell 25 in a mode that bolts penetrate through the through holes and are connected with nuts. The magnetic current changer shell 22 is fixed on the outer side of the flange plate, and the driven gear 9 of the main speed reducer is arranged on the inner side of the flange plate of the differential left shell 25 through bolts, so that the effects of changing the torque direction, reducing the speed and increasing the torque are achieved. The shell of the differential left shell 25 is provided with four circular through holes, and the differential right shell 2 is connected with the differential left shell 25 by bolts penetrating through the circular through holes and being fastened with nuts. The spherical annular groove is formed in the sleeve on the right side of the threaded flange of the left differential case 25 and used for containing the planet gear 1, and the circular plane is used for containing the half axle gear 5. The flange and the sleeve are integrally formed.

Four circular through holes are formed in the casing of the right differential case 2 and correspond to the four circular through holes of the left differential case 25. A hollow structure is arranged in the sleeve of the right differential case 2 and used for lubricating parts such as the planetary gear 1 and the side gear 5 in the differential. The lateral wing of the right differential case 2 is provided with a reinforcing rib for increasing the strength of the right differential case 2, a spherical annular groove part inside a sleeve of the right differential case 2 is used for accommodating the planetary gear 1, and a circular plane is used for accommodating the half axle gear 5. The rightmost side of the right differential case 2 is provided with a shoulder for mounting a differential bearing for mounting and rotational movement of the differential.

The half shaft 3 passes through the right differential case 2 and is matched with a half shaft gear 5 through splines to transmit torque to a right driving wheel.

The rightmost spline of the spline half shaft 16 is matched with the half shaft gear 5 and used for transmitting torque to a left driving wheel, the spline in the middle of the spline half shaft is matched with the spline of the magnetorheological device grating 15, when a coil of the magnetorheological device is electrified, magnetorheological fluid is changed into a solid-like body from liquid, a large resistance torque is generated in the magnetorheological device, and the torque is transmitted to the half shaft gear 5 through the spline between the magnetorheological device grating 15 and the spline half shaft 16, so that the differential effect is achieved. The side gear 5 is sleeved on the half shaft 3 and the spline half shaft 16 through splines and is sleeved in the circular planes of the differential right shell 2 and the differential left shell 25.

The planet gear 1 is meshed with the half shaft gear 5, and the planet gear 1 is sleeved on the cross shaft 26 through an inner circular hole. When the planetary gear 1 rotates relative to the cross shaft 26, the speeds of the left wheel and the right wheel are unequal, and the automobile is subjected to differential speed.

The cross shaft 26 is a cross-shaped optical axis, and is sleeved in four circular through holes formed when the differential left shell 25 and the differential right shell 2 are fixedly connected, so that the function of fixing the planetary gear 1 is achieved.

The magnetorheological device group mainly comprises a magnetorheological device shell 22, a magnetorheological device shell 19, a magnetorheological device grid 15, a coil 21, an electric brush 20, an electric brush box 12, an outer sealing ring 10 and an inner sealing ring 11. When the coil 21 of the magnetorheological unit is not electrified, the magnetorheological fluid is liquid, resistance moment is not generated between the magnetorheological unit shell 19 and the magnetorheological unit grating 15, and the differential mechanism is not self-locked. When the excitation coil 21 of the magnetorheological device group is electrified, magnetorheological fluid is changed into a solid-like body under the action of a magnetic field, the mechanical property of the liquid is changed, the shearing torque is increased, resistance torque is generated between the magnetorheological device shell 19 and the magnetorheological device grating 15, the resistance torque is transmitted to the half axle gear 5 through the magnetorheological device grating 15 through the spline half axle 16, the internal resistance of the differential is increased, and the differential is self-locked.

The magnetic current changer shell 22 is of a cylindrical structure, eight circular through grooves are formed in the wall of the outermost cylinder of the magnetic current changer shell 22, the circular through grooves correspond to the circular through grooves of the differential left shell 25 and the main speed reducer driven gear 9, and the magnetic current changer shell 22 is connected with the differential left shell 25 and the main speed reducer driven gear 9 respectively in a mode that bolts penetrate through the circular through grooves and are fixed by nuts. The wall of the magnetic flow changer shell 22 is provided with a small through hole for accommodating a lead wire of the coil 21. Four circular through holes are formed in the middle of the wall of the outermost cylinder of the magnetic current transformer shell 22 and used for fixing the magnetic current transformer shell 19. The leftmost shoulder of the magnetorheological housing 22 is used for mounting a differential bearing. The differential bearing inner ring is arranged on a shoulder at the leftmost side of the magnetic current transformer shell 22 and the rightmost side of the differential right shell 2, and the outer ring is arranged in a drive axle shell and used for rotating the whole model.

The magneto-rheological device shells 19 are of a symmetrical cylindrical structure, and the two magneto-rheological device shells 19 are fixed with bolts and nuts through holes of four square bosses on the outer sides. The two magnetorheological device shells 19 are fixed in the cylindrical inner cavity of the magnetorheological device shell 22 through the threaded holes on the leftmost side, and annular concave platforms formed by splicing the left side and the right side of the two magnetorheological device shells are used for accommodating the fixed bearings 17. The two magnetorheological device shells 19 are spliced to form six circular plate-shaped gratings and an inner cavity, magnetorheological fluid and the magnetorheological device gratings 15 are contained in the inner cavity, and sealing rings I18 are respectively arranged on two sides of the inner cavity to prevent leakage of the magnetorheological fluid.

The coil 21 is wound at the outer end of the magnetorheological device shell 19 and used for generating a magnetic field, a lead wire of the coil 21 is connected with the electric brush 20 through a small through hole in the side wall of the magnetorheological device shell 22, the electric brush 20 is connected and electrified with the electric brush box 12, the electric current is transmitted to the lead wire through the electric brush box 12 and the electric brush 20, the lead wire is electrified to generate the magnetic field, and the magnetorheological fluid is changed into a solid-like body from liquid under the action of the magnetic field.

And a sealing ring II 23 is arranged on the right side of the magnetorheological housing 19 and used for isolating oil of the differential and preventing the electric leakage of the coil 21.

The magnetic current transformer grating 15 is a disc-shaped structure, and splines in the magnetic current transformer grating are matched with splines of the spline half shaft 16 and used for transmitting self-locking torque of the magnetic current transformer. Seven circular plate-mounted gratings are arranged outside the magnetic magnetorheological damper in a staggered mode and are parallel and staggered with six circular plate-shaped gratings of the magnetorheological damper shell 19, magnetorheological fluid is changed into a solid-like body under the action of a magnetic field formed by electrifying the coil 21, resistance torque is formed between the magnetorheological damper gratings 15 and the magnetorheological damper shell 19 and is transmitted to the half-shaft gear 5 through the spline half shaft 16, internal resistance of the differential is increased, and a self-locking effect is generated.

The inner sealing ring 11 is of an annular structure, the middle cylindrical part is sleeved on the outer side of the magnetic current transformer shell 22, and the cylindrical part is provided with a through hole corresponding to the magnetic current transformer shell 22 and used for leading out a lead of the coil 21. The annular parts on the two sides of the inner sealing ring 11 are matched with the outer sealing ring 10 to form a sealing cavity to block lubricating oil in the axle housing.

The outer sealing ring 10 is of an annular structure, the middle cylindrical part and the electric brush box are arranged on the inner side of the axle housing, and the annular parts on the two sides are sleeved with the annular parts on the two sides of the inner sealing ring 11. The outer sealing ring 10 is rotatable relative to the inner sealing ring 11.

When the differential does not need to be self-locked, an external power supply does not supply power, the coil 21 does not form a magnetic field, the magnetorheological fluid is in a liquid property, no shear damping moment exists between the magnetorheological housing 19 and the magnetorheological grille 15, the internal resistance of the differential is ignored, at the moment, when the rotating speeds of the left wheel and the right wheel are different, the rotating speed of the left wheel is transmitted to a pair of half-shaft gears 5 in the differential through the spline half-shaft 16 and the rotating speed of the right wheel through the half-shafts, the rotating speeds of the two half-shaft gears 5 are different, the planetary gear 1 rotates relative to the cross shaft 26, and the differential generates a differential effect.

When differential self-locking is required, a power supply is provided from the outside and current is passed through the brush box and brushes 20 to the coil 21. The coil 21 is electrified to form a magnetic field, magnetorheological fluid is changed into a solid from liquid under the action of the magnetic field, a shear damping moment is formed between the magnetorheological device shell 19 and the magnetorheological device grid 15, the moment is transmitted to the side gear 5 through the magnetorheological device grid 15 and the spline half shaft 16, the internal resistance of the differential is increased, when the current intensity is enough, the magnetorheological device grid 15 cannot rotate relative to the magnetorheological device shell 19, the side gear 5 does not rotate relative to the differential device shell any more, the differential forms a self-locking effect, and the magnitude of the resistance moment can be controlled by controlling the intensity of the current in the coil 21.

It should be noted that the foregoing is only a preferred embodiment of the present invention and the technical principles applied. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail with reference to the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the scope of the present invention.

Claims (9)

1. A differential mechanism with a self-locking function based on magnetorheological fluid is characterized in that: the device consists of a differential set and a magnetorheological set;

the differential group mainly comprises a differential left shell (25), a differential right shell (2), a half axle gear (5), a planetary gear (1) and a main reducer driven gear (9); the differential left shell (25) comprises a flange plate and a sleeve positioned on the right side of the flange plate, and the inner end and the outer end of the flange plate are respectively fixed with a driven gear (9) of the main speed reducer and a magnetic current transformer shell (22) in the magnetic current transformer group; the differential right shell (2) comprises a sleeve, and a half shaft gear (5) and a planetary gear (1) meshed with the half shaft gear are sleeved in the sleeve of the differential left shell (25) and the sleeve of the differential right shell (2); the differential mechanism is characterized by further comprising a half shaft (3), a spline half shaft (16) and a cross shaft (26), wherein the half shaft (3) penetrates through the right differential mechanism shell (2) to be matched with an inner half shaft gear (5); the right side of the spline half shaft (16) is matched with a half shaft gear (5) in a left shell (25) of the differential mechanism; the two planetary gears (1) are sleeved on a cross shaft (26), and the cross shaft (26) is sleeved in four circular through holes formed when the differential left shell (25) and the differential right shell (2) are connected;

the magnetorheological unit also comprises two magnetorheological device shells (19), a magnetorheological device grating (15), a coil (21), an electric brush (20) and an electric brush box; the two magnetorheological device shells (19) are fixed in the magnetorheological device shell (22) and can be spliced into six circular plate-shaped gratings and an inner cavity, the magnetorheological device gratings (15) matched with the spline half shaft (16) are arranged in the magnetorheological device shells, bearings (17) are arranged on two sides of the magnetorheological device shells, and the left bearing (17) and the right bearing (17) are respectively connected with a shoulder on the left side of the magnetorheological device shell (22) and a flange neck of a differential left shell (25); the magnetorheological fluid is characterized in that a coil (21) is wound outside the magnetorheological device shell (19), a lead of the coil (21) is connected with an electric brush (20) through a small through hole in the side wall of the magnetorheological device shell (22), the electric brush (20) is connected with an electric brush box and electrified, current is transmitted to the lead through the electric brush (20) through the electric brush box, the lead is electrified to generate a magnetic field, and the magnetorheological fluid is changed from liquid to solid under the action of the magnetic field.

2. The differential with self-locking function based on magnetorheological fluid according to claim 1, characterized in that: the ring flange and the sleeve integrated into one piece of differential mechanism left side shell (25), it has eight to be used for connecting main reducer driven gear (9) and the circular through-hole of magnetic current transformer shell (22) to open on the ring flange, and it has four circular through-holes that are used for connecting differential mechanism right side shell (2) to open on the sleeve, and the sleeve is inside to be equipped with spherical annular, and differential mechanism left side shell (25) are connected with main reducer driven gear (9), magnetic current transformer shell (22) and differential mechanism right side shell (2) respectively through bolt and nut.

3. The differential with self-locking function based on magnetorheological fluid according to claim 1, characterized in that: it has four circular through-holes that are used for connecting differential left side shell (25) to open on differential right side shell (2) the casing, is equipped with hollow out construction and spherical annular in the sleeve, and differential right side shell (2) flank is equipped with the stiffening rib, and differential right side shell (2) rightmost side is equipped with a circular bead for install the differential bearing.

4. The differential with self-locking function based on magnetorheological fluid according to claim 1, characterized in that: the half shaft (3) penetrates through the right differential case (2) to be matched with the half shaft gear (5) through splines, the spline at the rightmost side of the spline half shaft (16) is matched with the half shaft gear (5), the spline in the middle of the spline half shaft is matched with the spline of the magnetic current transformer grating (15), and the half shaft gear (5) is sleeved on the half shaft (3) and the spline half shaft (16) through the splines and is sleeved in the circular plane of the right differential case (2) and the left differential case (25).

5. The differential with self-locking function based on magnetorheological fluid according to claim 1, characterized in that: the cross shaft (26) is a cross-shaped optical axis, and the planet gear (1) is sleeved on the cross shaft (26) through an inner circular hole.

6. The differential with self-locking function based on magnetorheological fluid according to claim 1, characterized in that: the magnetorheological device shell (22) is of a cylindrical structure, eight circular through grooves used for connecting a differential left shell (25) and a main speed reducer driven gear (9) are formed in the outermost cylinder wall of the magnetorheological device shell, four circular through holes used for fixing the magnetorheological device shell (19) are formed in the middle of the outermost cylinder wall of the magnetorheological device shell (22), and a shoulder is arranged on the leftmost side of the magnetorheological device shell (22) and used for mounting a differential bearing.

7. The differential with self-locking function based on magnetorheological fluid according to claim 1, characterized in that: the two magneto rheological shells (19) are of a symmetrical cylindrical structure, the two magneto rheological shells (19) penetrate through holes of four square bosses on the outer side through bolts and are fixed with nuts, the two magneto rheological shells (19) are fixed in a cylindrical inner cavity of the magneto rheological shell (22) through a threaded hole on the leftmost side, annular concave platforms formed by splicing the left side and the right side of the two magneto rheological shells are used for accommodating a fixed bearing (17), and sealing rings I (18) and a sealing ring II (23) are respectively installed on the two sides of the inner cavity of the two magneto rheological shells (19).

8. The differential with self-locking function based on magnetorheological fluid according to claim 1, characterized in that: the magnetic current changer grating (15) is of a disc-shaped structure, splines in the magnetic current changer grating are matched with splines of a spline half shaft (16), seven circular plate-mounted gratings are arranged outside the magnetic current changer grating in a staggered mode, the gratings are parallelly staggered with six circular plate-shaped gratings of a magnetic current changer shell (19), magnetic current changing into a solid-like body under the action of a magnetic field formed by electrifying a coil (21), resistance moment is formed between the magnetic current changer grating (15) and the magnetic current changer shell (19), and the resistance moment is transmitted to the half shaft gear (5) through the spline half shaft (16).

9. The differential with self-locking function based on magnetorheological fluid according to claim 1, characterized in that: the magnetorheological damper is characterized by further comprising an annular inner sealing ring (11) and an annular outer sealing ring (10), wherein a cylindrical part in the middle of the inner sealing ring (11) is sleeved on the outer side of the magnetorheological damper shell (22), a through hole corresponding to the magnetorheological damper shell (22) is formed in the cylindrical part, and annular parts on two sides of the inner sealing ring (11) are matched with the outer sealing ring (10) to form a sealing cavity; the cylindrical part and the electric brush box in the middle of the outer sealing ring (10) are installed on the inner side of the axle housing, the annular parts on the two sides are sleeved with the annular parts on the two sides of the inner sealing ring (11), and the outer sealing ring (10) can rotate relative to the inner sealing ring (11).

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