CN107061680B - Electric differential mechanism with torque directional distribution function - Google Patents

Electric differential mechanism with torque directional distribution function Download PDF

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CN107061680B
CN107061680B CN201710273431.9A CN201710273431A CN107061680B CN 107061680 B CN107061680 B CN 107061680B CN 201710273431 A CN201710273431 A CN 201710273431A CN 107061680 B CN107061680 B CN 107061680B
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gear
planet carrier
sun gear
planetary gear
differential
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CN107061680A (en
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王军年
杨斌
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Jilin University
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Jilin University
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16HGEARING
    • F16H48/00Differential gearings
    • F16H48/06Differential gearings with gears having orbital motion
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16HGEARING
    • F16H48/00Differential gearings
    • F16H48/38Constructional details

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Abstract

The invention discloses an electric differential with a torque directional distribution function, which comprises: a main drive mechanism; a bevel gear differential; a TV control drive mechanism for outputting control power; the first sun gear is coaxially and fixedly connected with the first half shaft, and the first gear ring is connected with the control output end; the second single-row planetary gear system is characterized in that a second ring gear is fixed on a driving axle housing, and a second planet carrier is fixedly connected with the first planet carrier; the second sun gear is supported on the first half shaft through a bearing; a third single-row planetary gear train, wherein a third sun gear is fixedly connected with the second sun gear, a third planet carrier is fixedly connected with the first half shaft, and a third gear ring is fixedly connected with the differential case; and the second single-row planetary gear train and the first single-row planetary gear train have the same characteristic parameters. The invention enables the driving torque of the automobile to be directionally distributed to the left wheel and the right wheel according to the control requirement of the control logic.

Description

Electric differential mechanism with torque directional distribution function
Technical Field
The invention belongs to the technical field of electric automobile transmission, and particularly relates to an electric differential with a torque directional distribution function.
Background
Due to the energy crisis and the increasing importance of environmental protection, new energy automobiles are the development direction of future automobiles, and electric automobiles are rapidly developed in the world. Compared with the traditional internal combustion engine automobile, the electric automobile has better economical efficiency and environmental protection, and has the characteristic of almost zero emission, so that the electric automobile has remarkable advantages in the aspect of environmental protection. Meanwhile, the electric automobile has better acceleration performance due to the characteristics of fast response, low speed, large torque and the like of the driving motor, the rotating speed and the torque of the motor are easy to obtain, and the electric automobile can be controlled more accurately. Therefore, the electric automobile has great development potential.
The electric automobile generally adopts a power assembly consisting of a motor and a drive axle or a power assembly consisting of the motor, a transmission and the drive axle to drive the automobile to run, and the electric automobile driven by the hub motor is not mass-produced due to the defects of large unsprung mass, poor heat dissipation of the hub motor and the like, so the drive axle is mostly contained in the power assembly of the existing electric automobile.
The differential is an important part in a drive axle, and due to the principle of differential and no differential torque of the differential, the driving torque of an automobile can only be equally distributed on the two sides of the left wheel and the right wheel, so that the ground adhesion force cannot be well utilized under the condition of uneven road surface adhesion, even unstable working conditions such as wheel slip and the like are easily caused on the side with low adhesion, and the adhesion capability of the driving wheels cannot be exerted. Meanwhile, when the vehicle turns at a high speed, the load is transferred from the inner wheel to the outer wheel, even if the ground adhesion is good, the adhesion capability of the outer wheel is higher than that of the inner wheel, and at the moment, when the torque is equally distributed to the inner wheel and the outer wheel by the traditional differential, the inner wheel reaches the adhesion limit to generate slip, so that the vehicle is unstable. If part of the torque of the inner wheels is transferred to the outer wheels, the lateral force margin of the inner wheels can be increased, the wheels are prevented from slipping, and an additional yaw moment can be generated on the whole vehicle, and the moment can help to push and guide the vehicle to turn, so that the turning maneuverability and the ultimate turning capability of the vehicle are improved. At present, the technology is applied to some high-end sports cars and high-end SUVs in the form of a torque directional distribution differential, such as the super four-wheel drive system (SH-AWD) of honda and the super active yaw control System (SAYC) of mitsubishi, but the technology is not applied to electric automobiles too much.
Disclosure of Invention
The invention aims to solve the defect that the left and right output torques of a differential are equal and cannot be adjusted, and provides an electric differential with a torque directional distribution function.
The technical scheme provided by the invention is as follows:
an electric differential with torque directional distribution, comprising:
a main driving mechanism which is arranged at one side of the differential mechanism, the output end of the main driving mechanism is connected with the differential mechanism shell, and the main driving mechanism can transmit the rotary power to the differential mechanism shell to drive the vehicle to run;
a TV control drive mechanism provided on the other side of the differential for outputting torque distribution control power;
the first single-row planetary gear train comprises a first sun gear, a first planetary gear, a first planet carrier and a first gear ring, wherein the first sun gear is coaxially and fixedly connected with a first half shaft, and the first gear ring is connected with the output end of the TV control driving mechanism;
the second single-row planetary gear train comprises a second sun gear, a second planet carrier and a second gear ring, wherein the second gear ring is fixed on the driving axle housing, and the second planet carrier is fixedly connected with the first planet carrier; the second sun gear is rotatably supported on the first half shaft;
the third single-row planetary gear train comprises a third sun gear, a third planetary gear, a third planet carrier and a third gear ring, wherein the third sun gear is fixedly connected with the second sun gear, the third sun gear is rotatably supported on the first half shaft, the third planet carrier is fixedly connected with the first half shaft, and the third gear ring is fixedly connected with the differential case;
wherein the second single-row planetary gear train and the first single-row planetary gear train have the same characteristic parameters.
Preferably, the TV control drive mechanism includes a TV control motor and a TV speed reduction mechanism.
Preferably, the TV control motor has a hollow output shaft, and the first half shaft is rotatably supported on and protrudes from the hollow output shaft.
Preferably, the TV deceleration mechanism includes:
the fourth single-row planetary gear train comprises a fourth sun gear, a fourth planetary gear, a fourth planet carrier and a fourth gear ring, the fourth sun gear is fixedly connected with the hollow output shaft, and the fourth gear ring is fixed on the drive axle housing;
and the fifth single-row planetary gear train comprises a fifth sun gear, a fifth planetary gear, a fifth planet carrier and a fifth gear ring, the fifth sun gear is fixedly connected with the fourth planet carrier, the fifth gear ring is fixed on the driving axle housing, and the fifth planet carrier is connected with the first gear ring as a control output end.
Preferably, the main drive mechanism includes a main drive motor and a main speed reduction mechanism.
Preferably, the main drive motor has a hollow output shaft, and the second axle shaft is rotatably supported on and extends out of the hollow output shaft.
Preferably, the main speed reducing mechanism includes:
the seventh single-row planetary gear train comprises a seventh sun gear, a seventh planet carrier and a seventh gear ring, the seventh sun gear is fixedly connected with the output shaft of the main driving motor, and the seventh gear ring is fixed on the driving axle housing;
a sixth single-row planetary gear train comprising a sixth sun gear, a sixth planet carrier and a sixth ring gear, the sixth sun gear being fixedly connected with the seventh planet carrier, the sixth ring gear being fixed on the drive axle housing, the sixth planet carrier being fixedly connected with the differential housing.
An electric differential with torque directional distribution functionality, comprising:
a main driving mechanism which is arranged at one side of the differential mechanism, the output end of the main driving mechanism is connected with the differential mechanism shell, and the main driving mechanism can transmit the rotary power to the differential mechanism shell to drive the vehicle to run;
a TV control drive mechanism provided on the other side of the differential for outputting torque distribution control power;
the first single-row double-stage planetary gear train comprises a first sun gear, a first double-stage planetary gear, a first planet carrier and a first gear ring, the first sun gear is coaxially and fixedly connected with a first half shaft, and the first gear ring is connected with the output end of the TV control driving mechanism;
the second single-row double-stage planetary gear train comprises a second sun gear, a second planet double-stage planetary gear, a second planet carrier and a second gear ring, wherein the second gear ring is fixed on the driving axle housing, and the second planet carrier is fixedly connected with the first planet carrier; the second sun gear is rotatably supported on the first half shaft;
the third single-row planetary gear train comprises a third sun gear, a third planetary gear, a third planet carrier and a third gear ring, wherein the third sun gear is fixedly connected with the second sun gear, the third sun gear is rotatably supported on the first half shaft, the third planet carrier is fixedly connected with the first half shaft, and the third gear ring is fixedly connected with the differential shell;
wherein the second single-row planetary gear train and the first single-row planetary gear train have the same characteristic parameters.
An electric differential with torque directional distribution, comprising:
a main driving mechanism which is arranged at one side of the differential mechanism, the output end of the main driving mechanism is connected with the differential mechanism shell, and the main driving mechanism can transmit the rotary power to the differential mechanism shell to drive the vehicle to run;
a TV control drive mechanism provided on the other side of the differential for outputting torque distribution control power;
the first single-row planetary gear train comprises a first sun gear, a first planetary gear, a first planet carrier and a first gear ring, wherein the first sun gear is coaxially and fixedly connected with a first half shaft, and the first gear ring is connected with the output end of the TV control driving mechanism;
the second single-row planetary gear train comprises a second sun gear, a second planet carrier and a second gear ring, wherein the second gear ring is fixed on the driving axle housing, and the second planet carrier is fixedly connected with the first planet carrier; the second sun gear is rotatably supported on the first half shaft;
the third single-row double-stage planetary gear train comprises a third sun gear, a third double-stage planetary gear, a third planet carrier and a third gear ring, wherein the third sun gear is fixedly connected with the second sun gear, the third sun gear is rotatably supported on the first half shaft, the third planet carrier is fixedly connected with the first half shaft, and the third gear ring is fixedly connected with the differential case;
wherein the second single-row planetary gear train and the first single-row planetary gear train have the same characteristic parameters.
An electric differential with torque directional distribution, comprising:
a main driving mechanism which is arranged at one side of the differential mechanism, the output end of the main driving mechanism is connected with the differential mechanism shell, and the main driving mechanism can transmit the rotary power to the differential mechanism shell to drive the vehicle to run;
a TV control drive mechanism provided on the other side of the differential for outputting torque distribution control power;
the first single-row double-stage planetary gear train comprises a first sun gear, a first double-stage planetary gear, a first planet carrier and a first gear ring, the first sun gear is coaxially and fixedly connected with a first half shaft, and the first gear ring is connected with the output end of the TV control driving mechanism;
the second single-row double-stage planetary gear train comprises a second sun gear, a second double-stage planetary gear, a second planet carrier and a second gear ring, wherein the second gear ring is fixed on the driving axle housing, and the second planet carrier is fixedly connected with the first planet carrier; the second sun gear is rotatably supported on the first half shaft;
the third single-row double-stage planetary gear train comprises a third sun gear, a third double-stage planetary gear, a third planet carrier and a third gear ring, wherein the third sun gear is fixedly connected with the second sun gear, the third sun gear is rotatably supported on the first half shaft, the third planet carrier is fixedly connected with the first half shaft, and the third gear ring is fixedly connected with the differential shell;
wherein the second single-row planetary gear train and the first single-row planetary gear train have the same characteristic parameters.
The beneficial effects of the invention are shown in the following aspects:
1. the electric differential with the torque directional distribution function provided by the invention overcomes the defect that the differential in the traditional drive axle is not differential and not torque-differential, so that the driving torque of an automobile can be directionally distributed to the left and right wheels according to the control requirement of control logic, the function of unequal distribution of the wheel torque of the left and right wheels is realized on the premise of not changing the longitudinal total driving torque, and the turning maneuverability and the driving pleasure of the automobile are improved.
2. According to the electric differential with the torque directional distribution function, the TV control motor and the main driving motor are coaxially arranged, the structure is more compact, and the arrangement space is reduced.
3. The electric differential with the torque directional distribution function belongs to sprung mass, so that unsprung mass cannot be obviously increased like a hub motor, and the influence on the smoothness of an automobile in running is small.
Drawings
FIG. 1 is a schematic structural diagram of an embodiment of an electric differential with torque directional distribution according to the present invention.
FIG. 2 is a schematic structural diagram of an electric differential with a torque directional distribution function according to an embodiment of the present invention.
FIG. 3 is a schematic diagram of an embodiment of an electric differential with torque directional distribution according to the present invention.
FIG. 4 is a schematic structural diagram of an electric differential with a torque directional distribution function according to the fourth embodiment of the present invention.
FIG. 5 is a schematic diagram of the torque flow direction of the electric differential with the torque directional distribution function in the straight running of the automobile.
FIG. 6 is a schematic diagram of the torque flow direction of the electric differential with the torque directional distribution function in normal turning of the automobile.
Fig. 7 is a schematic diagram of the torque flow direction of the electric differential with the torque directional distribution function in the invention when the automobile turns left and the torque directional distribution device works.
FIG. 8 is a schematic diagram of the torque flow direction of the electric differential with the torque directional distribution function when the vehicle turns right and the torque directional distribution device works.
Detailed Description
The present invention is further described in detail below with reference to the attached drawings so that those skilled in the art can implement the invention by referring to the description text.
Example one
As shown in FIG. 1, the present invention provides an electric differential with torque distribution function, which mainly comprises a torque directional distributor 2000, a conventional bevel gear differential 1400, a main drive motor reducing mechanism 1500 and a main drive motor 1002.
In the present embodiment, the torque directional divider 2000 is located on the left side of the driving axle (which may be exchanged with the main driving motor 1002 and disposed on the right side of the driving axle), and mainly comprises a TV control motor 1001, a TV speed reduction mechanism 1100, a double-row TV coupling mechanism 1200, and a single-row differential coupling mechanism 1300.
The TV control motor 1001 is a hollow shaft type inner rotor motor, the first half shaft 1402 connected with the left wheel penetrates through an inner hole of the hollow rotor shaft, the hollow shaft type inner rotor is in spline connection with the sun gear 1014 of the fourth planetary gear train 1010, and the output torque of the TV control motor 1001 is input to the fourth planetary gear train 1010. The TV control motor 1001 is supported on a first axle shaft 1402 by bearings, the stator of which and its housing are fixed to the transaxle case.
The TV reduction gear 1100 mainly includes a fourth planetary gear train 1010 and a fifth planetary gear train 1020. The fourth planetary gear train 1010 comprises a sun gear 1014, three planetary gears 1012 uniformly distributed on the circumference, a planet carrier 1013 and an inner gear ring 1011 fixed on a drive axle housing. The sun gear 1014 is splined to a hollow shaft type inner rotor of the TV control motor 1001, and the carrier 1013 is integrated with the sun gear 1024 of the fifth planetary gear train 1020. The fifth planetary gear train 1020 comprises a sun gear 1024, three planetary gears 1022 uniformly distributed on the circumference, a planet carrier 1023 and a ring gear 1021 fixed on the drive axle housing. The sun gear 1024 is supported on the first half shaft 1402 by a bearing, and the planet carrier 1023 is integrated with the ring gear 1031 of the first planetary gear train 1030.
It is preferable that the TV reduction mechanism 1100 be constituted by a single row planetary gear train, a multiple row planetary gear train, or other form of reduction mechanism, and therefore the form of shifting the reduction mechanism 1100 is not regarded as an innovation of the present invention.
The double row TV coupling 1200 mainly comprises a first planetary gear train 1030 and a second planetary gear train 1040, which have to have the same row characteristic parameters and the same row type. The first planetary gear train 1030 comprises a sun gear 1034, three planetary gears 1032 which are evenly distributed on the circumference, a planet carrier 1033 and an inner gear 1031. The ring gear 1031 is integrated with the planet carrier 1023 of the fifth planetary gear train 1020, the sun gear 1034 is connected with the first half shaft 1402 through a spline, and the planet carrier 1033 is integrated with the planet carrier 1043 of the second planetary gear train 1040. The second planetary gear train 1040 includes a sun gear 1044, three planetary gears 1042 uniformly distributed circumferentially, a planet carrier 1043, and an annulus gear 1041 fixed on a drive axle housing. The sun gear 1044 is integrated with the sun gear 1054 of the third planetary gear train 1050, and the sun gear 1044 is supported on the first half shaft 1402 through a bearing.
The single planetary row differential coupling mechanism 1300 is mainly composed of a third planetary gear train 1050. The third planetary gear train 1050 includes a sun gear 1054, three planetary gears 1052 circumferentially and uniformly distributed, a planet carrier 1053, and an inner gear ring 1051. The sun gear 1054 and the second sun gear 1044 are integrated and supported on the first half shaft 1402 through a bearing, the planet carrier 1053 is splined to the first half shaft 1402, and the ring gear 1051 is integrated with the differential case 1401.
The conventional bevel gear differential 1400 is basically constructed of a differential case 1401, a first half shaft 1402, a second half shaft 1403, a first half shaft gear 1404, a second half shaft gear 1405, two conical planetary gears 1406 and 1407, and a pinion shaft 1408. Wherein a first side gear 1404 is spline-connected to a first half shaft 1402, a second side gear 1405 is spline-connected to a second half shaft 1403, and a differential case 1401 is supported on the second half shaft 1403 by bearings.
The main drive motor speed reduction mechanism 1500 is located on the right side of the transaxle and mainly comprises a sixth planetary gear train 1060 and a seventh planetary gear train 1070. The sixth planetary gear train 1060 comprises a sun gear 1064, three planet gears 1062 uniformly distributed circumferentially, a planet carrier 1063 and an annular gear 1061 fixed on the drive axle housing. The carrier 1063 is integrated with the differential case 1401, the sun gear 1064 is integrated with the carrier 1073 of the seventh planetary gear train 1070, and the sun gear 1064 is supported on the second half shaft 1403 by a bearing. The seventh row planetary gear train 1070 comprises a sun gear 1074, three planet gears 1072 uniformly distributed circumferentially, a planet carrier 1073, and an annular gear 1071 fixed on a drive axle housing. Wherein the sun gear 1074 is splined to the hollow inner rotor shaft of the main drive motor 1002.
It is preferable that the main drive motor reduction mechanism 1500 may be constituted by a single row planetary gear train, a multiple row planetary gear train, or other form of reduction mechanism, and thus changing the form of the main drive motor reduction mechanism 1500 is not considered as an innovation of the present invention.
The main drive motor 1002 is located on the right side of the drive axle and is a hollow shaft type inner rotor motor, and a second half shaft 1403 connected with the right wheel penetrates through an inner hole of the hollow rotor shaft. The hollow shaft type inner rotor is spline-connected to a sun gear 1074 of the seventh planetary gear train 1070, and the main drive motor 1002 can input drive torque into the main drive motor reduction mechanism 1500 through the sun gear 1074, and act on the differential case 1401, and finally equally divide the drive torque into the first half shaft 1402 and the second half shaft 1403. The main drive motor 1002 is supported on a second axle shaft 1403 via bearings, the stator and its housing being fixed to the drive axle housing.
Example two
As shown in fig. 2, in the present embodiment, the first planetary gear train 1030 and the second planetary gear train 1040 in the double planetary row TV coupling mechanism 1200 are both single planetary rows, and the third planetary gear train 1050 in the single planetary row differential coupling mechanism 1300 is a double planetary row, and the schematic diagram is shown.
EXAMPLE III
In the present embodiment, as shown in fig. 3, the first planetary gear train 1030 and the second planetary gear train 1040 in the double planetary row TV coupling mechanism 1200 are both double planetary gear rows, and the third planetary gear train 1050 in the single planetary row differential coupling mechanism 1300 is a single planetary gear row, and the schematic is shown.
In the fourth embodiment of the present invention, the following,
in the present embodiment, as shown in fig. 4, the first planetary gear train 1030 and the second planetary gear train 1040 in the double-row TV coupling mechanism 1200 are both double-stage planetary gear rows, and the third planetary gear train 1050 in the single-row differential coupling mechanism 1300 is a double-stage planetary gear row, and the schematic structure is shown in the figure.
The solutions shown in fig. 1 to 4 are all the practical structural solutions of the electric differential with the torque directional distribution function according to the present invention, but in consideration of the inertia loss and the operation efficiency of the system, the solution shown in fig. 1 is the best preferred solution, and then the solution shown in fig. 3, and then the solutions shown in fig. 2 and 4 are used.
The electric differential with the torque directional distribution function has the following working principle:
the operation principle will be described by taking the schematic structure of the embodiment of the electric differential with the torque directional distribution function shown in fig. 1 as an example.
When the automobile runs straight, the driving torque of the left wheel and the right wheel is the same, no torque distribution is needed, so that no control electric signal is generated in the TV control motor 1001, the TV control motor is not started, the automobile is driven only by the main drive motor 1002, the torque output by the main drive motor 1002 is added through the main drive motor speed reducing mechanism 1500 and acts on the differential shell 1401, and due to the principle of torque equal division of the traditional bevel gear differential mechanism 1400, the torque acting on the differential shell 1401 is equally distributed to the first half shaft 1402 and the second half shaft 1403, and the automobile is driven to run. If the rotating direction of the wheels is set to be a positive direction when the automobile is driven, and otherwise, the rotating direction is a negative direction. At this time, the rotational speeds of the differential case 1401, the first half shaft 1402, and the second half shaft 1403 are the same, and the planet gears 1052 of the third planetary gear train 1050 rotate only with the differential case 1401 without rotating on its own axis, so the carrier 1053 and the sun gear 1054 rotate at the same speed. Since the rotational speeds of the sun gear 1034 of the first planetary gear train 1030 and the carrier 1053 of the third planetary gear train 1050 are the same, and the sun gear 1044 of the second planetary gear train 1040 and the sun gear 1054 of the third planetary gear train 1050 are integrated, the sun gear 1034 of the first planetary gear train 1030 and the sun gear 1044 of the second planetary gear train 1040 rotate at a constant speed. Since first planetary gear train 1030 and second planetary gear train 1040 share a carrier and the rotational speeds of both sun gears are also the same, the rotational speed of ring gear 1031 is also the same as the rotational speed of ring gear 1041, ring gear 1041 is fixed and the rotational speed is 0, so the rotational speed of ring gear 1031 is also 0. Since the TV reduction gear 1100 changes only the magnitude of the torque output from the TV control motor 1001 and does not change the positive and negative directions of the output torque, when the vehicle travels straight, the rotational speed of the inner rotor of the TV control motor 1001 is also 0, the TV control motor is not started and does not output torque, the vehicle is driven only by the main drive motor 1002, and the torque distribution flow is as shown in fig. 5.
When the automobile normally performs differential turning, the driving torque of the left wheel and the right wheel is the same, and no torque distribution is needed, so that no control electric signal is generated in the TV control motor 1001, the TV control motor is not started, the automobile is driven only by the main drive motor 1002, the torque output by the main drive motor 1002 is added through the torque of the speed reducing mechanism 1500 of the main drive motor and acts on the differential shell 1401, and due to the principle of torque equal division of the traditional bevel gear differential mechanism 1400, the torque acting on the differential shell 1401 is equally distributed to the first half shaft 1402 and the second half shaft 1403, and the automobile is driven to run.
Taking the example of the normal differential left-turn of the automobile, if the rotation direction of the wheels is set to be a positive direction when the automobile is driven, and vice versa, the rotation direction is a negative direction. Then the single planet row differential coupling 1050 is given by the single planet row speed formula:
n S5 +k 5 n R5 -(k 5 +1)n PC5 =0
in the formula n S5 For the third planetary gear train 1050 sun gear 1054 speed, n R5 For the third planetary gear 1051 ring gear speed, n PC5 Planet carrier rotation speed, k, for the third planetary gear train 1053 5 Is the characteristic parameter of the planet row of the third planet wheel system. Since the vehicle is turning left, the differential case 1401 rotates at a speed greater than the first half shaft 1402, so that:
n S5 <n R5
therefore:
n S5 <n PC5
that is, the rotational speed of the sun gear 1054 in the third planetary gear train 1050 is less than the rotational speed of the carrier 1053, so the rotational speed of the sun gear 1034 in the first planetary gear train 1030 is greater than the rotational speed of the sun gear 1044 in the second planetary gear train 1040 for the double row TV coupling 1200. Since the first planetary gear train 1030 shares a carrier with the second planetary gear train 1040, the double planetary line TV coupling mechanism 1200 includes:
n S3 +kn R3 =n S4 +kn R4
in the formula n S3 For the first planetary gear train 1030 sun gear 1034 rotational speed, n R3 For the first planetary gear train 1030 the speed, n, of the ring gear 1031 S4 The rotational speed of the sun gear 1044 of the second planetary gear train 1040, n R4 Is the speed of ring gear 1041 of second planetary gear train 1040, and k is the characteristic parameter of the planetary gear train of first planetary gear train 1030 and second planetary gear train 1040. And because:
n S3 >n S4 and n is R4 =0
Therefore:
n R3 <0
that is, the rotational speed of ring gear 1031 of first planetary gear train 1030 is negative, and therefore the rotational speed of the inner rotor of TV control motor 1001 is also negative. Therefore, when the vehicle normally performs a differential left turn, the TV control motor 1001 has no electric signal input and no torque output, and the hollow shaft type inner rotor of the TV control motor is dragged by the torque divider 2000 to rotate in a negative direction. The torque distribution flow is shown in fig. 6.
In the same way, when the automobile normally rotates in the right direction at a differential speed, the TV control motor 1001 has no electric signal input and no torque output, and the hollow shaft type inner rotor of the TV control motor is dragged by the torque distributor 2000 to rotate in the positive direction. The torque split flow is also shown in fig. 6.
When the vehicle is turning at high speeds, it is desirable to directionally distribute the inboard wheel torque to the outboard wheels to improve turning maneuverability. If the rotation direction of the wheels is set to be a positive direction when the automobile is driven, and the rotation direction is a negative direction when the automobile is driven, left turning of the automobile is taken as an example for analysis. At this time, the motor controller controls the TV to control the output torque-T of the motor 1001 0 (T 0 Positive value), the torque is reduced and torque is increased through the TV reduction mechanism 1100, and the torque input to the ring gear 1031 in the double planetary TV coupling mechanism 1200 is-iT 0 Where i is the gear ratio of the TV reduction mechanism 1100. The torque input by the sun gear 1034 to the first axle 1402 in the first planetary gear train 1030 is therefore
Figure BDA0001276215110000131
The torque input by the TV control motor 1001 to the sun gear 1054 in the single row differential coupling 1300 is £ greater or greater>
Figure BDA0001276215110000132
The torque that the planet carrier 1053 in the third planetary gear train 1050 inputs into the first half-shaft 1402 is £ greater>
Figure BDA0001276215110000133
The torque input into the differential case 1401 from the ring gear 1051 is £ v>
Figure BDA0001276215110000134
A torque equally divided by the differential case 1401 into the first half-shaft 1402 and the second half-shaft 1403 is>
Figure BDA0001276215110000135
Therefore, the torque finally input to the first half-shaft 1402 by the control motor 1001 is the sum of the torque input to the first half-shaft 1402 from the sun gear 1034 in the first planetary gear train 1030, the torque input to the first half-shaft 1402 from the carrier 1053 in the third planetary gear train 1050, and the torque equally divided into three parts from the differential case 1401 to the first half-shaft 1402, and the result is |/h>
Figure BDA0001276215110000136
The torque which is ultimately input into the second half-shaft 1403 by the TV control motor 1001 is ≥>
Figure BDA0001276215110000137
As can be seen from the above, the moments input into the first axle 1402 and the second axle 1403 by the TV control motor 1001 are equally inverted, so that the total longitudinal driving torque is not changed, and the torque of the wheels on the left side connected to the first axle 1402 decreases, and the torque of the wheels on the right side connected to the second axle 1403 increases, and a yaw moment contributing to a left turn can be generated, improving the maneuverability of the vehicle for a left turn. Note that, at this time, the rotational speed of the TV control motor 1001 is the same as that at the normal differential left turn. The torque distribution flow at this time is shown in fig. 7. It should be noted that if the TV control motor outputs a positive torque at this time, the driving torque will be directionally distributed from the right side wheels to the left side wheels, and a yaw moment will be generated to prevent the vehicle from oversteering, for maintaining vehicle stability.
In the same way, when the automobile turns right at a high speed, the motor controller controls the TV control motor 1001 to output a forward torque, and can generate a yaw moment which is beneficial to turning right on the premise of not changing the total longitudinal driving torque, so that the right turning maneuverability of the automobile is improved. Note that, at this time, the rotational speed of the TV control motor 1001 is the same as that at the normal differential right rotation. The torque distribution flow at this time is shown in fig. 8. It should be noted that if the TV control motor outputs a negative torque at this time, the driving torque will be directionally distributed from the left wheels to the right wheels, and a yaw moment will be generated to prevent the vehicle from oversteering, for maintaining the stability of the vehicle.
While embodiments of the invention have been described above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the invention pertains, and further modifications may readily be made by those skilled in the art, it being understood that the invention is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.

Claims (10)

1. An electric differential with torque directional distribution, comprising:
the main driving mechanism is arranged on one side of the differential mechanism, the output end of the main driving mechanism is connected with the differential mechanism shell, and the main driving mechanism can transmit the rotary power to the differential mechanism shell, equally divide the power and transmit the power to the first half shaft and the second half shaft of the differential mechanism to drive the vehicle to run;
a TV control drive mechanism provided on the other side of the differential for outputting torque distribution control power;
the first single-row planetary gear train comprises a first sun gear, a first planetary gear, a first planet carrier and a first gear ring, wherein the first sun gear is coaxially and fixedly connected with a first half shaft, and the first gear ring is connected with the output end of the TV control driving mechanism;
the second single-row planetary gear train comprises a second sun gear, a second planet carrier and a second gear ring, wherein the second gear ring is fixed on the driving axle housing, and the second planet carrier is fixedly connected with the first planet carrier; the second sun gear is rotatably supported on the first half shaft;
the third single-row planetary gear train comprises a third sun gear, a third planetary gear, a third planet carrier and a third gear ring, wherein the third sun gear is fixedly connected with the second sun gear, the third sun gear is rotatably supported on the first half shaft, the third planet carrier is fixedly connected with the first half shaft, and the third gear ring is fixedly connected with the differential case;
wherein the second single-row planetary gear train and the first single-row planetary gear train have the same characteristic parameters.
2. The electric differential with torque vectoring function as claimed in claim 1, wherein said TV control drive mechanism comprises a TV control motor and a TV speed reduction mechanism.
3. An electric differential with torque vectoring function as claimed in claim 2, wherein said TV control motor has a hollow output shaft, said first half shaft being rotatably supported on and extending out of said hollow output shaft.
4. The electric differential with torque vectoring function as claimed in claim 2, wherein said TV speed reduction mechanism comprises:
the fourth single-row planetary gear train comprises a fourth sun gear, a fourth planetary gear, a fourth planet carrier and a fourth gear ring, the fourth sun gear is fixedly connected with the hollow output shaft, and the fourth gear ring is fixed on the drive axle housing;
and the fifth single-row planetary gear train comprises a fifth sun gear, a fifth planet carrier and a fifth gear ring, the fifth sun gear is fixedly connected with the fourth planet carrier, the fifth gear ring is fixed on the driving axle housing, and the fifth planet carrier is connected with the first gear ring as a control output end.
5. An electric differential with torque vectoring function as claimed in claim 1, wherein said primary drive mechanism comprises a primary drive motor and a primary reduction mechanism.
6. An electric differential with torque directional distribution as set forth in claim 5 wherein said primary drive motor has a hollow output shaft with a second axle shaft rotatably supported thereon and extending therefrom.
7. The electric differential with torque directional distribution function according to claim 5, characterized in that the final drive mechanism includes:
the seventh single-row planetary gear train comprises a seventh sun gear, a seventh planet carrier and a seventh gear ring, the seventh sun gear is fixedly connected with the output shaft of the main driving motor, and the seventh gear ring is fixed on the driving axle housing;
a sixth single-row planetary gear train comprising a sixth sun gear, a sixth planet carrier and a sixth ring gear, the sixth sun gear being fixedly connected with the seventh planet carrier, the sixth ring gear being fixed on the drive axle housing, the sixth planet carrier being fixedly connected with the differential housing.
8. An electric differential with torque directional distribution, comprising:
a main driving mechanism which is arranged at one side of the differential mechanism, the output end of the main driving mechanism is connected with the differential mechanism shell, and the main driving mechanism can transmit the rotary power to the differential mechanism shell to drive the vehicle to run;
a TV control drive mechanism provided on the other side of the differential for outputting torque distribution control power;
the first single-row double-stage planetary gear train comprises a first sun gear, a first double-stage planetary gear, a first planet carrier and a first gear ring, wherein the first sun gear is coaxially and fixedly connected with a first half shaft, and the first gear ring is connected with the output end of the TV control driving mechanism;
the second single-row double-stage planetary gear train comprises a second sun gear, a second double-stage planetary gear, a second planet carrier and a second gear ring, the second gear ring is fixed on the driving axle housing, and the second planet carrier is fixedly connected with the first planet carrier; the second sun gear is rotatably supported on the first half shaft;
the third single-row planetary gear train comprises a third sun gear, a third planetary gear, a third planet carrier and a third gear ring, wherein the third sun gear is fixedly connected with the second sun gear, the third sun gear is rotatably supported on the first half shaft, the third planet carrier is fixedly connected with the first half shaft, and the third gear ring is fixedly connected with the differential shell;
the second single-row double-stage planetary gear train and the first single-row double-stage planetary gear train have the same characteristic parameters.
9. An electric differential with torque directional distribution, comprising:
a main driving mechanism which is arranged at one side of the differential mechanism, the output end of the main driving mechanism is connected with the differential mechanism shell, and the main driving mechanism can transmit the rotary power to the differential mechanism shell to drive the vehicle to run;
a TV control drive mechanism provided on the other side of the differential for outputting torque distribution control power;
the first single-row planetary gear train comprises a first sun gear, a first planetary gear, a first planet carrier and a first gear ring, wherein the first sun gear is coaxially and fixedly connected with a first half shaft, and the first gear ring is connected with the output end of the TV control driving mechanism;
the second single-row planetary gear train comprises a second sun gear, a second planet carrier and a second gear ring, wherein the second gear ring is fixed on the driving axle housing, and the second planet carrier is fixedly connected with the first planet carrier; the second sun gear is rotatably supported on the first half shaft;
the third single-row double-stage planetary gear train comprises a third sun gear, a third double-stage planetary gear, a third planet carrier and a third gear ring, wherein the third sun gear is fixedly connected with the second sun gear, the third sun gear is rotatably supported on the first half shaft, the third planet carrier is fixedly connected with the first half shaft, and the third gear ring is fixedly connected with the differential shell;
wherein the second single-row planetary gear train and the first single-row planetary gear train have the same characteristic parameters.
10. An electric differential with torque directional distribution, comprising:
the main driving mechanism is arranged on one side of the differential mechanism, the output end of the main driving mechanism is connected with the differential mechanism shell, and the main driving mechanism can transmit the rotary power to the differential mechanism shell to drive the vehicle to run;
a TV control drive mechanism provided on the other side of the differential for outputting torque distribution control power;
the first single-row double-stage planetary gear train comprises a first sun gear, a first double-stage planetary gear, a first planet carrier and a first gear ring, wherein the first sun gear is coaxially and fixedly connected with a first half shaft, and the first gear ring is connected with the output end of the TV control driving mechanism;
the second single-row double-stage planetary gear train comprises a second sun gear, a second double-stage planetary gear, a second planet carrier and a second gear ring, wherein the second gear ring is fixed on the driving axle housing, and the second planet carrier is fixedly connected with the first planet carrier; the second sun gear is rotatably supported on the first half shaft;
the third single-row double-stage planetary gear train comprises a third sun gear, a third double-stage planetary gear, a third planet carrier and a third gear ring, wherein the third sun gear is fixedly connected with the second sun gear, the third sun gear is rotatably supported on the first half shaft, the third planet carrier is fixedly connected with the first half shaft, and the third gear ring is fixedly connected with the differential shell;
the second single-row double-stage planetary gear train and the first single-row double-stage planetary gear train have the same characteristic parameters.
CN201710273431.9A 2017-04-21 2017-04-21 Electric differential mechanism with torque directional distribution function Active CN107061680B (en)

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JP2006327583A (en) * 2006-06-15 2006-12-07 Toyota Motor Corp Drive device for vehicle
CN104675951A (en) * 2015-02-11 2015-06-03 吉林大学 Electric differential with double-row planetary gear torque directional distribution mechanism
CN206682251U (en) * 2017-04-21 2017-11-28 吉林大学 A kind of electric differential mechanism with torque fixed direction allocation function

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Publication number Priority date Publication date Assignee Title
US8544588B2 (en) * 2007-11-09 2013-10-01 Ford Global Technologies, Llc Power takeoff for all-wheel-drive systems
JP5141605B2 (en) * 2009-03-12 2013-02-13 三菱自動車工業株式会社 Driving force adjustment device

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2006327583A (en) * 2006-06-15 2006-12-07 Toyota Motor Corp Drive device for vehicle
CN104675951A (en) * 2015-02-11 2015-06-03 吉林大学 Electric differential with double-row planetary gear torque directional distribution mechanism
CN206682251U (en) * 2017-04-21 2017-11-28 吉林大学 A kind of electric differential mechanism with torque fixed direction allocation function

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