1. A gear assembly, comprising:

a first bevel gear;

a second bevel gear engaged with the first bevel gear with a backlash therebetween;

one end of the rotating arm is rotatably arranged, the first bevel gear is arranged on the rotating arm, and the rotating arm is used for driving the first bevel gear to rotate so as to adjust the tooth gap;

a positioning member detachably provided at the other end of the rotating arm,

wherein the positioning part is used for fixing the rotating arm.

2. The gear assembly according to claim 1, further comprising:

the axis of the rotating shaft and the reference circle of the second bevel gear are in the same plane;

one end of the rotating arm is sleeved on the rotating shaft and rotates around the axis of the rotating shaft.

3. The gear assembly according to claim 2,

the distance from the first bevel gear to the rotating shaft is greater than half of the length of the rotating arm.

4. A gear assembly according to claim 2 or 3,

the first bevel gear is arranged at the other end of the rotating arm.

5. A gear assembly according to claim 2 or 3,

the first bevel gear is arranged between the rotating shaft and the positioning piece.

6. The gear assembly according to claim 2 or 3, further comprising:

the first bevel gear, the second bevel gear and the rotating arm are arranged in the shell.

7. The gear assembly according to claim 6,

the rotating shaft is arranged on the shell, and the rotating arm is rotatably connected with the shell through the rotating shaft.

8. The gear assembly according to claim 6,

the shell is provided with a limiting part, and the positioning piece is used for being matched with the limiting part to fix the rotating arm.

9. The gear assembly according to claim 6,

the shell is internally provided with a containing cavity, the rotating arm is arranged in the containing cavity, and the rotating arm is in clearance fit with the containing cavity.

10. A gear assembly according to any one of claims 1-3,

the diameter of the first bevel gear is smaller than the diameter of the second bevel gear.

11. The gear assembly according to any one of claims 1 to 3, further comprising:

and the bearing is sleeved on the first bevel gear, and the first bevel gear is rotationally connected with the rotating arm through the bearing.

12. A gear assembly according to any one of claims 1-3,

at least one of the first bevel gear and the second bevel gear is a hypoid gear.

13. A gear assembly according to any one of claims 1-3,

the axis of the first bevel gear and the axis of the second bevel gear are perpendicular to each other.

14. An artificial joint, comprising:

a gear assembly according to any one of claims 1-13.

15. A robot, comprising:

an artificial limb;

the artificial joint of claim 14, wherein the artificial limb is provided with the artificial joint.

Background

With the development of science and technology, robots are widely used in various fields. The joints of the robot are generally provided with gear reduction mechanisms. The gear reduction mechanism often uses bevel gears. Due to the reciprocating motion characteristic of the robot joint and the high requirement on the rotation precision, the backlash between the gear teeth is a key factor influencing the rotation precision.

In the related art, for the adjustment of the backlash, it is general to measure and perform a dimension chain calculation, determine the thickness of the shim according to the calculation result, and then perform the assembly. If not appropriate after assembly, reinstallation is required, resulting in inefficient backlash adjustment.

Disclosure of Invention

Embodiments according to the present application aim to at least improve the technical problems of low back clearance adjustment efficiency and the like in the prior art or the related art.

In view of this, it is an object according to embodiments of the present application to provide a gear assembly.

It is another object of embodiments according to the present application to provide an artificial joint.

It is a further object according to embodiments of the present application to provide a robot.

To achieve the above object, an embodiment according to a first aspect of the present application provides a gear assembly comprising: a first bevel gear; the second bevel gear is meshed with the first bevel gear, and a gear gap is formed between the second bevel gear and the first bevel gear; the device comprises a rotating arm, a first gear and a second gear, wherein one end of the rotating arm is rotatably arranged, a first bevel gear is arranged on the rotating arm, and the rotating arm is used for driving the first bevel gear to rotate so as to adjust a tooth gap; and the positioning piece is detachably arranged at the other end of the rotating arm and is used for fixing the rotating arm.

Embodiments according to a second aspect of the present application provide an artificial joint comprising: a gear assembly as in any one of the embodiments of the first aspect above.

Embodiments according to a third aspect of the present application provide a robot comprising: an artificial limb; an artificial joint according to any one of the embodiments of the second aspect above. The artificial limb is provided with an artificial joint.

According to an embodiment of the present application, a gear assembly is provided, in which a first bevel gear is provided on the swivel arm and rotates with the swivel arm, so that a backlash between the first bevel gear and the second bevel gear can be adjusted. The backlash is adjusted by rotating the rotating arm, namely the first bevel gear can be close to or far away from the second bevel gear by rotating the rotating arm, so that the purpose of adjusting the backlash is realized, the adjusting mode is simple and flexible, and the adjusting efficiency is high. And the rotating arm is a common structure, has low requirement on processing precision and is easy to realize. Furthermore, the gear assembly also comprises a positioning part which is detachably arranged at the other end of the rotating arm, and after the adjustment of the tooth clearance is finished, the rotating arm can be fixed by the positioning part and is not rotated any more, and the tooth clearance is fixed. Meanwhile, the positioning piece can be disassembled, and when the tooth clearance is not properly adjusted, the positioning piece can be disassembled and readjusted, and the positioning piece can be reinstalled.

Additional aspects and advantages of embodiments in accordance with the present application will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of embodiments in accordance with the present application.

Drawings

FIG. 1 is a cross-sectional structural schematic view of a gear assembly according to one embodiment of the present application;

FIG. 2 is a cross-sectional structural schematic view of a gear assembly according to another embodiment of the present application;

FIG. 3 is a perspective view of a gear assembly according to one embodiment of the present application;

FIG. 4 is a tooth clearance adjustment schematic of a gear assembly according to one embodiment of the present application;

FIG. 5 is a tooth clearance adjustment schematic of a gear assembly according to another embodiment of the present application;

FIG. 6 is a logical schematic block diagram of an artificial joint according to one embodiment of the present application;

fig. 7 is a logical schematic block diagram of a robot according to another embodiment of the present application.

Reference numerals:

10 gear assembly, 100 shell, 102 first bevel gear, 104 second bevel gear, 106 rotating arm, 108 positioning piece, 110 rotating shaft, 112 bearing, 20 artificial joint, 30 robot, 300 artificial limb.

Detailed Description

In order that the above objects, features and advantages of embodiments according to the present application may be more clearly understood, embodiments according to the present application will be described in further detail below with reference to the accompanying drawings and detailed description. It should be noted that features of embodiments according to the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth to provide a thorough understanding of embodiments according to the present application, however, embodiments according to the present application may be practiced in other ways than those described herein, and therefore the scope of protection afforded by embodiments according to the present application is not limited by the specific embodiments disclosed below.

Some embodiments provided in accordance with the present application are described below with reference to fig. 1-7.

Example 1

As shown in fig. 1-5, a gear assembly 10 is provided according to an embodiment of the present application. The gear assembly 10 includes a first bevel gear 102, a second bevel gear 104, a swivel arm 106, and a positioning member 108.

The first bevel gear 102 and the second bevel gear 104 are meshed with each other. The first bevel gear 102 and the second bevel gear 104 are used to transmit torque to each other. There is a backlash between the first bevel gear 102 and the second bevel gear 104. One end of the swivel arm 106 is rotatably provided. The first bevel gear 102 is provided on the swivel arm 106. The rotating arm 106 is used for rotating the first bevel gear 102. The first bevel gear 102 approaches or moves away from the second bevel gear 104 as the swivel arm 106 rotates. Through the arrangement of the rotating arm 106, the first bevel gear 102 can be driven to adjust the backlash. As shown in fig. 2, a positioning member 108 is detachably provided at the other end of the rotating arm 106 and is used to fix the rotating arm 106.

According to the embodiment of the first aspect of the present application, a gear assembly 10 is provided in which the first bevel gear 102 is provided on the swivel arm 106 and rotates with the swivel arm 106, so that the backlash between the first bevel gear and the second bevel gear 104 can be adjusted. The backlash is adjusted by rotating the rotating arm 106, that is, the first bevel gear 102 can be moved closer to or away from the second bevel gear 104 by rotating the rotating arm 106, so as to achieve the purpose of adjusting the backlash. Moreover, the rotating arm 106 is a common structure, has low requirement on machining precision and is easy to realize. Further, the gear assembly 10 further includes a positioning member 108 detachably disposed at the other end of the rotating arm 106, and after the adjustment of the backlash is completed, the rotating arm 106 can be fixed by the positioning member 108 so as not to rotate any more, and the backlash is fixed. Meanwhile, the positioning element 108 can be removed, and when the backlash is improperly adjusted, the positioning element 108 can be removed, readjusted, and the positioning element 108 can be reinstalled.

Compared with the prior art that the backlash is adjusted by selecting shims with different thicknesses through measurement and calculation, the gear assembly 10 provided by the embodiment of the present application can adjust the backlash by simply rotating the rotating arm 106. Meanwhile, by the positioning member 108, the rotating arm 106 can be fixed after the tooth gap is adjusted in place, and accordingly, the tooth gap is fixed. The gear assembly 10 provided by the embodiment of the application has the advantages of simple and convenient tooth clearance adjusting mode, high adjusting efficiency, simple production, low requirement on machining precision and easiness in implementation.

Example 2

A gear assembly 10 is provided according to another embodiment of the present application. The gear assembly 10 includes a first bevel gear 102, a second bevel gear 104, a swivel arm 106, a swivel shaft 110, and a positioning member 108.

As shown in fig. 3, the first bevel gear 102 and the second bevel gear 104 are engaged with each other. The first bevel gear 102 and the second bevel gear 104 are used to transmit torque to each other. There is a backlash between the first bevel gear 102 and the second bevel gear 104. One end of the rotating arm 106 is sleeved on the rotating shaft 110 and is rotatably arranged through the rotating shaft 110. The first bevel gear 102 is provided on the swivel arm 106. The rotating arm 106 is used for rotating the first bevel gear 102. The first bevel gear 102 approaches or moves away from the second bevel gear 104 as the swivel arm 106 rotates. Through the arrangement of the rotating arm 106, the first bevel gear 102 can be driven to adjust the backlash. A positioning member 108 is detachably provided at the other end of the rotating arm 106 and is used to fix the rotating arm 106.

According to the embodiment of the first aspect of the present application, a gear assembly 10 is provided in which the first bevel gear 102 is provided on the swivel arm 106 and rotates with the swivel arm 106, so that the backlash between the first bevel gear and the second bevel gear 104 can be adjusted. The backlash is adjusted by rotating the rotating arm 106, that is, the first bevel gear 102 can be moved closer to or away from the second bevel gear 104 by rotating the rotating arm 106, so as to achieve the purpose of adjusting the backlash. Moreover, the rotating arm 106 is a common structure, has low requirement on machining precision and is easy to realize. Further, the gear assembly 10 further includes a positioning member 108 detachably disposed at the other end of the rotating arm 106, and after the adjustment of the backlash is completed, the rotating arm 106 can be fixed by the positioning member 108 so as not to rotate any more, and the backlash is fixed. Meanwhile, the positioning element 108 can be removed, and when the backlash is improperly adjusted, the positioning element 108 can be removed, readjusted, and the positioning element 108 can be reinstalled.

It will be appreciated that the swivel arm 106 may rotate about the axis of the swivel shaft 110. In some embodiments, the shaft 110 and the arm 106 are fixedly coupled and rotate together. In other embodiments, the rotating arm 106 is rotatably disposed on the rotating shaft 110.

Further, the second bevel gear 104 has a reference circle. The axis of the rotating shaft 110 is in the same plane as the reference circle. The axis of the rotating shaft 110 and the reference circle of the second bevel gear 104 are arranged in the same plane, so that the relationship between the rotation angle and the backlash of the first bevel gear 102 can be measured and calculated. It is also advantageous to shorten the length of swivel arm 106, thereby reducing the turning radius of first bevel gear 102, and accordingly, the volume of swivel arm 106 and the entire gear assembly 10 can be reduced, saving space.

Example 3

A gear assembly 10 is provided according to another embodiment of the present application. The gear assembly 10 includes a first bevel gear 102, a second bevel gear 104, a swivel arm 106, a swivel shaft 110, and a positioning member 108.

The first bevel gear 102 and the second bevel gear 104 are meshed with each other. The first bevel gear 102 and the second bevel gear 104 are used to transmit torque to each other. There is a backlash between the first bevel gear 102 and the second bevel gear 104. One end of the rotating arm 106 is sleeved on the rotating shaft 110 and is rotatably arranged through the rotating shaft 110. The first bevel gear 102 is provided on the swivel arm 106. The rotating arm 106 is used for rotating the first bevel gear 102. The first bevel gear 102 approaches or moves away from the second bevel gear 104 as the swivel arm 106 rotates. Through the arrangement of the rotating arm 106, the first bevel gear 102 can be driven to adjust the backlash. A positioning member 108 is detachably provided at the other end of the rotating arm 106 and is used to fix the rotating arm 106.

According to the embodiment of the first aspect of the present application, a gear assembly 10 is provided in which the first bevel gear 102 is provided on the swivel arm 106 and rotates with the swivel arm 106, so that the backlash between the first bevel gear and the second bevel gear 104 can be adjusted. The backlash is adjusted by rotating the rotating arm 106, that is, the first bevel gear 102 can be moved closer to or away from the second bevel gear 104 by rotating the rotating arm 106, so as to achieve the purpose of adjusting the backlash. Moreover, the rotating arm 106 is a common structure, has low requirement on machining precision and is easy to realize. Further, the gear assembly 10 further includes a positioning member 108 detachably disposed at the other end of the rotating arm 106, and after the adjustment of the backlash is completed, the rotating arm 106 can be fixed by the positioning member 108 so as not to rotate any more, and the backlash is fixed. Meanwhile, the positioning element 108 can be removed, and when the backlash is improperly adjusted, the positioning element 108 can be removed, readjusted, and the positioning element 108 can be reinstalled.

It will be appreciated that the swivel arm 106 may rotate about the axis of the swivel shaft 110. In some embodiments, the shaft 110 and the arm 106 are fixedly coupled and rotate together. In other embodiments, the rotating arm 106 is rotatably disposed on the rotating shaft 110.

Further, the second bevel gear 104 has a reference circle. The axis of the rotating shaft 110 is in the same plane as the reference circle. The axis of the rotating shaft 110 and the reference circle of the second bevel gear 104 are arranged in the same plane, so that the relationship between the rotation angle and the backlash of the first bevel gear 102 can be measured and calculated. It is also advantageous to shorten the length of swivel arm 106, thereby reducing the turning radius of first bevel gear 102, and accordingly, the volume of swivel arm 106 and the entire gear assembly 10 can be reduced, saving space.

In one possible embodiment, the distance from the first bevel gear 102 to the rotation shaft 110 is greater than one-half of the length of the swivel arm 106. Limiting the distance from the first bevel gear 102 to the rotation axis 110 to be greater than half the length of the rotation arm 106 is advantageous in that the axis of the first bevel gear 102 is as far away from the rotation axis 110 as possible, and accordingly, the meshing point between the first bevel gear 102 and the second bevel gear 104 can be as far away from the rotation axis 110 as possible. Thus, the farther the distance between the meshing point and the rotation shaft 110 is, the larger the rotation radius of the first bevel gear 102 with respect to the rotation shaft 110, in the case where the length of the swivel arm 106 is constant. The larger the radius of rotation, the same degree of rotation, the smaller the change in distance between the first bevel gear 102 and the second bevel gear 104, and the higher the accuracy of adjustment of backlash. In short, the second bevel gear 104 is disposed on the rotating arm 106 as far as possible from the rotating shaft 110, which is advantageous for improving the adjustment accuracy of the backlash.

Example 4

A gear assembly 10 is provided according to yet another embodiment of the present application. The gear assembly 10 includes a first bevel gear 102, a second bevel gear 104, a swivel arm 106, a swivel shaft 110, and a positioning member 108.

The first bevel gear 102 and the second bevel gear 104 are meshed with each other. The first bevel gear 102 and the second bevel gear 104 are used to transmit torque to each other. There is a backlash between the first bevel gear 102 and the second bevel gear 104. One end of the rotating arm 106 is sleeved on the rotating shaft 110 and is rotatably arranged through the rotating shaft 110. A first bevel gear 102 is provided at the other end of the swivel arm 106. The rotating arm 106 is used for rotating the first bevel gear 102. The first bevel gear 102 approaches or moves away from the second bevel gear 104 as the swivel arm 106 rotates. Through the arrangement of the rotating arm 106, the first bevel gear 102 can be driven to adjust the backlash. A positioning member 108 is detachably provided at the other end of the rotating arm 106 and is used to fix the rotating arm 106.

According to the embodiment of the first aspect of the present application, a gear assembly 10 is provided in which the first bevel gear 102 is provided on the swivel arm 106 and rotates with the swivel arm 106, so that the backlash between the first bevel gear and the second bevel gear 104 can be adjusted. The backlash is adjusted by rotating the rotating arm 106, that is, the first bevel gear 102 can be moved closer to or away from the second bevel gear 104 by rotating the rotating arm 106, so as to achieve the purpose of adjusting the backlash. Moreover, the rotating arm 106 is a common structure, has low requirement on machining precision and is easy to realize. Further, the gear assembly 10 further includes a positioning member 108 detachably disposed at the other end of the rotating arm 106, and after the adjustment of the backlash is completed, the rotating arm 106 can be fixed by the positioning member 108 so as not to rotate any more, and the backlash is fixed. Meanwhile, the positioning element 108 can be removed, and when the backlash is improperly adjusted, the positioning element 108 can be removed, readjusted, and the positioning element 108 can be reinstalled.

It will be appreciated that the swivel arm 106 may rotate about the axis of the swivel shaft 110. In some embodiments, the shaft 110 and the arm 106 are fixedly coupled and rotate together. In other embodiments, the rotating arm 106 is rotatably disposed on the rotating shaft 110.

Further, the second bevel gear 104 has a reference circle. The axis of the rotating shaft 110 is in the same plane as the reference circle. The axis of the rotating shaft 110 and the reference circle of the second bevel gear 104 are arranged in the same plane, so that the relationship between the rotation angle and the backlash of the first bevel gear 102 can be measured and calculated. It is also advantageous to shorten the length of swivel arm 106, thereby reducing the turning radius of first bevel gear 102, and accordingly, the volume of swivel arm 106 and the entire gear assembly 10 can be reduced, saving space.

It should be noted that the first bevel gear 102 is disposed at the other end of the swivel arm 106, that is, over a limited length of the swivel arm 106, to maximize the distance between the first bevel gear 102 and the rotating shaft 110. By maximizing the distance between the rotation shaft 110 and the first bevel gear 102 on the rotation arm 106, the adjustment accuracy of the backlash can be maximized accordingly. Specifically, in the case where the length of the swivel arm 106 is limited, the farther the distance between the meshing point and the rotation shaft 110 is, the larger the rotation radius of the first bevel gear 102 with respect to the rotation shaft 110 is. The larger the radius of rotation, the same degree of rotation, the smaller the change in distance between the first bevel gear 102 and the second bevel gear 104, and the higher the accuracy of adjustment of backlash. Therefore, the second bevel gear 104 is provided at the other end of the swivel arm 106, which is advantageous for maximally improving the adjustment accuracy of the backlash.

Example 5

A gear assembly 10 is provided according to yet another embodiment of the present application. The gear assembly 10 includes a first bevel gear 102, a second bevel gear 104, a swivel arm 106, a swivel shaft 110, and a positioning member 108.

The first bevel gear 102 and the second bevel gear 104 are meshed with each other. The first bevel gear 102 and the second bevel gear 104 are used to transmit torque to each other. There is a backlash between the first bevel gear 102 and the second bevel gear 104. One end of the rotating arm 106 is sleeved on the rotating shaft 110 and is rotatably arranged through the rotating shaft 110. A first bevel gear 102 is provided at the other end of the swivel arm 106. The rotating arm 106 is used for rotating the first bevel gear 102. The first bevel gear 102 approaches or moves away from the second bevel gear 104 as the swivel arm 106 rotates. Through the arrangement of the rotating arm 106, the first bevel gear 102 can be driven to adjust the backlash. A positioning member 108 is also provided at the other end of the rotatable arm 106. A positioning member 108 is detachably provided on the rotating arm 106 and serves to fix the rotating arm 106.

According to the embodiment of the first aspect of the present application, a gear assembly 10 is provided in which the first bevel gear 102 is provided on the swivel arm 106 and rotates with the swivel arm 106, so that the backlash between the first bevel gear and the second bevel gear 104 can be adjusted. The backlash is adjusted by rotating the rotating arm 106, that is, the first bevel gear 102 can be moved closer to or away from the second bevel gear 104 by rotating the rotating arm 106, so as to achieve the purpose of adjusting the backlash. Moreover, the rotating arm 106 is a common structure, has low requirement on machining precision and is easy to realize. Further, the gear assembly 10 further includes a positioning member 108 detachably disposed at the other end of the rotating arm 106, and after the adjustment of the backlash is completed, the rotating arm 106 can be fixed by the positioning member 108 so as not to rotate any more, and the backlash is fixed. Meanwhile, the positioning element 108 can be removed, and when the backlash is improperly adjusted, the positioning element 108 can be removed, readjusted, and the positioning element 108 can be reinstalled.

It will be appreciated that the swivel arm 106 may rotate about the axis of the swivel shaft 110. In some embodiments, the shaft 110 and the arm 106 are fixedly coupled and rotate together. In other embodiments, the rotating arm 106 is rotatably disposed on the rotating shaft 110.

Further, the second bevel gear 104 has a reference circle. The axis of the rotating shaft 110 is in the same plane as the reference circle. The axis of the rotating shaft 110 and the reference circle of the second bevel gear 104 are arranged in the same plane, so that the relationship between the rotation angle and the backlash of the first bevel gear 102 can be measured and calculated. It is also advantageous to shorten the length of swivel arm 106, thereby reducing the turning radius of first bevel gear 102, and accordingly, the volume of swivel arm 106 and the entire gear assembly 10 can be reduced, saving space.

It should be noted that the first bevel gear 102 is disposed at the other end of the swivel arm 106, that is, over a limited length of the swivel arm 106, to maximize the distance between the first bevel gear 102 and the rotating shaft 110. By maximizing the distance between the rotation shaft 110 and the first bevel gear 102 on the rotation arm 106, the adjustment accuracy of the backlash can be maximized accordingly. Specifically, in the case where the length of the swivel arm 106 is limited, the farther the distance between the meshing point and the rotation shaft 110 is, the larger the rotation radius of the first bevel gear 102 with respect to the rotation shaft 110 is. The larger the radius of rotation, the same degree of rotation, the smaller the change in distance between the first bevel gear 102 and the second bevel gear 104, and the higher the accuracy of adjustment of backlash. Therefore, the second bevel gear 104 is provided at the other end of the swivel arm 106, which is advantageous for maximally improving the adjustment accuracy of the backlash.

Further, the positioning member 108 is disposed on a side of the first bevel gear 102 away from the rotating shaft 110. Alternatively, first bevel gear 102 is disposed between positioning member 108 and rotating shaft 110. The positioning element 108 is disposed on a side of the first bevel gear 102 away from the rotating shaft 110, i.e., the distance from the positioning element 108 to the rotating shaft 110 is greater than the distance from the first bevel gear 102 to the rotating shaft 110. During operation, the force generated by the meshing transmission between the first bevel gear 102 and the second bevel gear 104 has a torque, herein designated by the first torque, relative to the rotational axis 110. The positioning element 108 is used to fix the other end of the rotating arm 106 after the backlash adjustment is completed, so that the positioning element 108 also has a torque relative to the rotating shaft 110, which may be referred to as a second torque. Since the distance from the positioning member 108 to the rotating shaft 110 is greater than the distance from the first bevel gear 102 to the rotating shaft 110, the moment arm of the second torque is greater than that of the first torque according to the lever principle. Therefore, only a small fixing force is required at the position of the positioning member 108 to keep the rotating arm 106 stable, which is beneficial to reducing the size and volume of the positioning member 108, reducing the occupied space and lightening and miniaturizing the gear assembly 10. Meanwhile, the force arm is larger, so that labor is saved when the positioning piece 108 is detached for adjusting the backlash, and the convenience for adjusting the backlash is improved.

Example 6

A gear assembly 10 is provided according to yet another embodiment of the present application. The gear assembly 10 includes a housing 100, a first bevel gear 102, a second bevel gear 104, a swivel arm 106, and a positioning member 108.

A cavity is provided in the housing 100. The cavities are adapted to receive a first bevel gear 102, a second bevel gear 104, a swivel arm 106 and a positioning member 108. First bevel gear 102, and second bevel gear 104 are intermeshed. The first bevel gear 102 and the second bevel gear 104 are used to transmit torque to each other. There is a backlash between the first bevel gear 102 and the second bevel gear 104. One end of the swivel arm 106 is rotatably provided. The first bevel gear 102 is provided on the swivel arm 106. The rotating arm 106 is used for rotating the first bevel gear 102. The first bevel gear 102 approaches or moves away from the second bevel gear 104 as the swivel arm 106 rotates. Through the arrangement of the rotating arm 106, the first bevel gear 102 can be driven to adjust the backlash. A positioning member 108 is detachably provided at the other end of the rotating arm 106 and is used to fix the rotating arm 106.

According to the embodiment of the first aspect of the present application, a gear assembly 10 is provided in which the first bevel gear 102 is provided on the swivel arm 106 and rotates with the swivel arm 106, so that the backlash between the first bevel gear and the second bevel gear 104 can be adjusted. By the arrangement of the housing 100, protection can be provided for the first bevel gear 102, the second bevel gear 104 and other components, and maintenance materials such as cavity lubricating oil and the like can be conveniently accommodated, so that the gear assembly 10 can keep stable operation for a long time. The backlash is adjusted by rotating the rotating arm 106, that is, the first bevel gear 102 can be moved closer to or away from the second bevel gear 104 by rotating the rotating arm 106, so as to achieve the purpose of adjusting the backlash. Moreover, the rotating arm 106 is a common structure, has low requirement on machining precision and is easy to realize. Further, the gear assembly 10 further includes a positioning member 108 detachably disposed at the other end of the rotating arm 106, and after the adjustment of the backlash is completed, the rotating arm 106 can be fixed by the positioning member 108 so as not to rotate any more, and the backlash is fixed. Meanwhile, the positioning element 108 can be removed, and when the backlash is improperly adjusted, the positioning element 108 can be removed, readjusted, and the positioning element 108 can be reinstalled.

Compared with the prior art that the backlash is adjusted by selecting shims with different thicknesses through measurement and calculation, the gear assembly 10 provided by the embodiment of the present application can adjust the backlash by simply rotating the rotating arm 106. Meanwhile, by the positioning member 108, the rotating arm 106 can be fixed after the tooth gap is adjusted in place, and accordingly, the tooth gap is fixed. The gear assembly 10 provided by the embodiment of the application has the advantages of simple and convenient tooth clearance adjusting mode, high adjusting efficiency, simple production, low requirement on machining precision and easiness in implementation.

It is understood that the rotation shaft 110 is provided on the housing 100. The shaft 110 is fixedly coupled to one of the housing 100 and the arm 106, and is rotatably coupled to the other such that the arm 106 can rotate relative to the housing 100.

In other embodiments, the shaft 110 is rotatably coupled to both the housing 100 and the arm 106.

Further, the housing 100 is provided with a stopper. The limiting part can be a screw hole, a limiting groove and other structures. After the adjustment of the backlash is completed, the positioning member 108 fixes the rotating arm 106 while one end of the positioning member 108 is engaged with the stopper portion, so that the position of the positioning member 108 is fixed, thereby fixing the rotating arm 106.

In some embodiments, the positioning member 108 is a bolt, the limiting portion is a plurality of screw holes on the housing 100, and the positioning member 108 is bolted into one of the screw holes and cooperates with a different screw hole to achieve adjustment of the backlash.

In other embodiments, the positioning member 108 is a pin, and the limiting portion is a plurality of limiting holes or limiting grooves formed in the housing 100, and the positioning member 108 is inserted into the limiting holes or limiting grooves to limit the rotation of the rotating arm 106.

It will be appreciated that the arm 106 is smaller than the size of the housing to facilitate rotation or swinging within the housing.

In any of the above embodiments, the diameter of first bevel gear 102 and the diameter of second bevel gear 104 are not equal, and the diameter of first bevel gear 102 is smaller. The diameter of first bevel gear 102 is smaller, and accordingly, first bevel gear 102 is smaller in size and weight, and therefore is easier to rotate. This is advantageous in reducing the force for backlash adjustment and improving the convenience and flexibility of backlash adjustment.

It is understood that the gear assembly 10 also includes a bearing 112. First bevel gear 102 is sleeved with a bearing 112 so that first bevel gear 102 can rotate relative to tumbler 106 through bearing 112 to transmit torque to second bevel gear 104. Specifically, first bevel gear 102 is capable of rotating about its axis to engage second bevel gear 104 and transmit torque. At the same time, the first bevel gear 102 can rotate around the rotating shaft 110 along with the rotating arm 106, so as to achieve the purpose of adjusting the backlash. The number of the bearings 112 may be one or more. A plurality of bearings 112 are spaced to facilitate multi-point fixing of first bevel gear 102 and to improve the stability of operation of first bevel gear 102.

In the above embodiment, the first bevel gear 102 is a hypoid gear. Or the second bevel gear 104 is a hypoid gear. Alternatively, first bevel gear 102 and second bevel gear 104 are both hypoid gears.

It will be appreciated that the axis of first bevel gear 102 is perpendicular to the axis of second bevel gear 104.

Example 7

As shown in fig. 6, an embodiment according to a second aspect of the present application provides an artificial joint 20 comprising: the gear assembly 10 according to any of the embodiments of the first aspect described above.

According to an embodiment of the second aspect of the present application, there is provided an artificial joint 20 including the gear assembly 10 according to any one of the embodiments of the first aspect, so as to have all the advantages of the embodiments, and the details are not repeated herein.

Example 8

As shown in fig. 7, an embodiment according to a third aspect of the present application provides a robot 30 including: an artificial limb 300; the artificial joint 20 according to any one of the embodiments of the second aspect described above. The artificial limb 300 is provided with an artificial joint 20.

According to the robot 30 provided by the embodiment of the third aspect of the present application, the artificial joint 20 of any one of the embodiments of the second aspect is included, so that all the advantages of the embodiments are achieved, and the details are not repeated herein.

Example 9

The gear assembly 10 according to an embodiment of the present application provides a solution for adjusting the backlash quickly and easily when the robot 30 mounts the gear assembly 10.

The gear assembly 10 of this embodiment, which may be applied to any shaft of the robot 30, includes a device for adjusting backlash of bevel gears in the gear assembly 10.

In this particular embodiment, the axis of rotation 110A of the first bevel gear 102 and the axis of rotation 110B of the second bevel gear 104 are perpendicular to each other. Wherein first bevel gear 102 is smaller in diameter than second bevel gear 104. The backlash adjusting device is mounted on the housing 100. The backlash adjustment mechanism includes a first bevel gear 102, a swivel arm 106 and a bearing 112.

The projecting portion of the rotating arm 106 is coaxial with the first bevel gear 102 and is mounted in the cavity of the housing 100. In particular, the cavity comprises a passage H. The diameter of the passage H is larger than the diameter of the boss on the swivel arm 106.

The rotation shaft 110 passes through a fitting hole of the rotation arm 106 and is installed in a hole of the housing 100. Swivel arm 106 is mounted for rotation about axis C of pivot 110. The rotating shaft 110 of this embodiment can be any component with positioning and fastening functions.

The axis of rotation 110C of the shaft 110 is in the same plane as the reference circle of the second bevel gear 104 and is as far away from the point of engagement as possible. The position of first bevel gear 102 relative to second bevel gear 104 in the radial and axial directions is adjusted by the oscillation of swivel arm 106 about axis C. The axial position of the first bevel gear 102 is related to the backlash, so as to achieve the purpose of adjusting the backlash. After the backlash adjustment is completed, the rotating arm 106 is fixed to the housing 100 by the positioning member 108;

as shown in fig. 4 and 5, the swinging of the rotating arm 106 simultaneously causes the position of the first bevel gear 102 to change along the second bevel gear 104 in the axial direction Δ y and the radial direction Δ X, where X is the distance from the swinging center to the meshing point, i.e., the distance between the axis C and the axis a. When Δ y < < X, θ ≈ 0 °, Δ X < < Δ y when Δ y is small, the influence of the tooth contact area by Δ X can be ignored.

Axis a and axis B are perpendicular to each other. Axis a is offset from axis B. In some embodiments, the housing 100 has a passage H that is larger than the boss diameter of the swivel arm 106.

The embodiments provided by the present application are described in detail above with reference to the drawings, and by the embodiments, the convenience and the efficiency of adjusting the tooth clearance are effectively improved, and the precision of machining the adjusting structure of the tooth clearance on the gear assembly 10 is reduced.

In embodiments according to the present application, the terms "first", "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; the term "plurality" means two or more unless expressly limited otherwise. The terms "mounted," "connected," "fixed," and the like are to be construed broadly, and for example, "connected" may be a fixed connection, a removable connection, or an integral connection; "coupled" may be direct or indirect through an intermediary. Specific meanings of the above terms in the embodiments according to the present application can be understood by those of ordinary skill in the art as the case may be.

In the description herein, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example in accordance with the application. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above embodiments are merely preferred embodiments according to the present application, and are not intended to limit the embodiments according to the present application, and those skilled in the art may make various modifications and variations to the embodiments according to the present application. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the embodiments according to the present application shall be included in the protection scope of the embodiments according to the present application.