CN215129596U - Be applied to difference compensation mechanism of manipulator - Google Patents

Abstract

The utility model belongs to the technical field of medical instrument, especially, relate to a be applied to difference compensation mechanism of manipulator. The utility model discloses, can cause the tightness or the lax of wire rope when moving other positions to among the prior art, thereby cause wire rope to drive the binding clip and take place slight offset, can't realize the independent control of binding clip, inconvenient medical personnel carry out the problem of operating, a differential compensation mechanism who is applied to the manipulator is provided, binding clip seat, the binding clip subassembly, second control rope and tensioning wheel subassembly, still include the differential compensation subassembly, rotating the in-process, the change trend that length was established on the differential compensation subassembly is pressed to second control rope and the change trend that length was established on the tensioning wheel subassembly is pressed to second control rope. The utility model discloses be equipped with difference compensation assembly, the second control rope is established because of the pressure and is compensated by difference compensation assembly in the tight or lax all can compensate offset that the change of take-up pulley surface length leads to, guarantees that the binding clip subassembly is by independent control.

Description

Be applied to difference compensation mechanism of manipulator

Technical Field

The utility model belongs to the technical field of medical instrument, especially, relate to a be applied to difference compensation mechanism of manipulator.

Background

Surgical forceps are used for holding human tissue during surgery. In the prior art, a steel wire rope is used for controlling the rotation and the opening and closing of a forceps head. But the movable joint that sets up on the operation pincers has many places, can the active position when not more than binding clip department, can cause during the activity other positions wire rope's to tighten or lax to cause wire rope to drive binding clip and take place slight offset, can't realize the independent control of binding clip, inconvenient medical personnel operate.

For example, the chinese invention patent application discloses a detachable laparoscopic clip applier [ application No.: 201911172052.6], the invention patent application includes: the left shaft is provided with a first U grooved wheel and a second U grooved wheel, the first U grooved wheel is rigidly connected with a first forceps mouth, the second U grooved wheel is rigidly connected with a second forceps mouth, and the front joint is connected with the rear joint through the right shaft; the right shaft is provided with a plurality of guide devices, the rear joint is internally provided with a plurality of linear steering engines corresponding to the guide devices, and the linear steering engines control the guide devices to enable the two forceps mouths to carry out picking actions in all directions.

The patent application of the invention has the advantages of small volume, light weight, strong flexibility, difficult damage to branches and leaves and high freedom of movement among complex branches and leaves, but still has the problems and can not be applied to the field of medical treatment.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the above-mentioned problem, a can guarantee difference compensation mechanism of being applied to manipulator of binding clip subassembly independent control is provided.

In order to achieve the above purpose, the utility model adopts the following technical proposal:

the utility model provides a be applied to difference compensation mechanism of manipulator, includes binding clip seat and rotates the binding clip subassembly of being connected with the binding clip seat, and the second control rope is connected on the binding clip subassembly and the pulling second control rope can make the binding clip subassembly take place to rotate, be equipped with the tensioning wheel subassembly that is used for preventing the second control rope from taking place to relax on the binding clip seat, the second control rope is pressed and is established on the tensioning wheel subassembly, still includes difference compensation assembly, the second control rope is pressed and is established on difference compensation assembly surface, and in the rotation process, the change trend of second control rope pressure length on difference compensation assembly and the change trend of second control rope pressure length on tensioning wheel subassembly are opposite, the turned angle scope of binding clip subassembly is greater than 135 degrees.

In the above differential compensation mechanism applied to the manipulator, the differential compensation assembly includes an operation frame and a fixed frame which are rotatably connected, the operation frame is provided with a wire pressing wheel and a differential compensation wheel, an axial lead of the differential compensation wheel coincides with a rotation axis of the operation frame rotating relative to the fixed frame, the second control rope is sequentially arranged at the upper end of the wire pressing wheel and the lower end of the differential compensation wheel, or the second control rope is sequentially arranged at the lower end of the wire pressing wheel and the upper end of the differential compensation wheel.

In foretell difference compensation mechanism who is applied to manipulator, be equipped with the runner assembly between binding clip subassembly and the binding clip seat, runner assembly one end rotates with the binding clip seat and is connected, and the other end rotates with the binding clip subassembly and is connected, and the direction of rotation of runner assembly is inequality with the direction of rotation of binding clip subassembly, and first control rope is connected on the runner assembly and rotate the handling frame and can pull first control rope and make the runner assembly take place to rotate.

In the above-mentioned difference compensation mechanism applied to the manipulator, the mechanism further comprises a driving wheel coaxially arranged with the difference compensation wheel, and one end of the first control rope far away from the rotating assembly is fixedly connected to the driving wheel.

In the above-mentioned difference compensation mechanism applied to the manipulator, the tensioning wheel assembly includes a first tensioning wheel, a second tensioning wheel and a third tensioning wheel, which are sequentially arranged, the first tensioning wheel is connected to the chuck base, the second tensioning wheel and the third tensioning wheel are connected to the rotating assembly, the second control rope includes a left control rope and a right control rope, the first tensioning wheel, the second tensioning wheel, the third tensioning wheel, the wire pressing wheel and the difference compensation wheel are all provided with two and respectively correspond to the left control rope and the right control rope, the left control rope is sequentially arranged at the upper end of the wire pressing wheel, the lower end of the difference compensation wheel, the lower end of the first tensioning wheel, the upper end of the second tensioning wheel and the lower end of the third tensioning wheel, and the right control rope is sequentially arranged at the lower end of the wire pressing wheel, the upper end of the difference compensation wheel, the upper end of the first tensioning wheel, the lower end of the second tensioning wheel and the upper end of the third tensioning wheel.

In the above-described difference compensation mechanism applied to the robot arm, the length of the second control rope pressed on the difference compensation pulley and the second tension pulley is a fixed value.

In the difference compensation mechanism applied to the manipulator, the operation frame is provided with a first limiting surface, the fixing frame is provided with a second limiting surface, the operation frame is rotated to enable the first limiting surface to be pressed on the second limiting surface, an included angle between the first limiting surface and the second limiting surface is 20-45 degrees, and the diameter of the difference compensation wheel is 2-4.5 times of that of the second tensioning wheel.

In foretell difference compensation mechanism who is applied to manipulator, the runner assembly is including rotating the seat, the one end of rotating the seat is equipped with first rotation wheel, first rotation wheel rotates with the binding clip seat to be connected, first control rope is connected on first rotation wheel and the first rotation wheel of pulling can drive takes place to rotate, the one end of rotating the seat and keeping away from first rotation wheel rotates with the binding clip subassembly to be connected, it installs the axle still to fixedly connected with on the seat to rotate, and spacing round of cover is established and is installed epaxially and be connected with the installation hub rotation, the second control rope is pressed and is established on spacing taking turns.

In the above-mentioned difference compensation mechanism applied to the manipulator, the binding clip assembly includes a left binding clip and a right binding clip, one end of the left binding clip close to the rotating assembly is provided with a second rotating wheel, the second rotating wheel is rotatably connected with the rotating assembly, one end of the right binding clip close to the rotating assembly is provided with a third rotating wheel, the third rotating wheel is rotatably connected with the rotating assembly, the second control rope is connected to the second rotating wheel and the third rotating wheel, and the second control rope is pulled to rotate the second rotating wheel and/or the third rotating wheel, and the second control rope includes a left control rope connected to the second rotating wheel and a right control rope connected to the third rotating wheel.

In the above-mentioned difference compensation mechanism applied to the manipulator, an interference prevention step extends from an outer edge of the second rotating wheel and/or the third rotating wheel.

Compared with the prior art, the utility model has the advantages of:

1. the utility model discloses be equipped with difference compensation assembly, rotate the in-process, the second control rope pressure is established the length variation trend on difference compensation assembly and is just opposite with the take-up pulley subassembly, and the second control rope is established the tension that leads to at take-up pulley subassembly surface length change or is lax because of the pressure and all can compensate by difference compensation assembly and offset like this to prevent that the second control rope from influencing the position of binding clip subassembly because of the change of tight degree, guarantee that the binding clip subassembly is by independent control.

2. The utility model discloses still be equipped with the tensioning wheel subassembly to the realization is to the tension of second control rope, prevents that the second control rope from lax and breaking away from predetermined orbital problem emergence to appear at runner assembly pivoted in-process.

3. The utility model discloses a mutually supporting of runner assembly and binding clip subassembly has realized towards equidirectional rotation, can realize multi-direction rotation at the operation in-process, and the flexible operation, demand under the adaptable complicated operation environment.

Drawings

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

fig. 2 is a schematic structural diagram of the present invention;

FIG. 3 is an enlarged view at A in FIG. 1;

FIG. 4 is an enlarged view at B in FIG. 1;

FIG. 5 is a schematic structural view of the holding end of the present invention;

FIG. 6 is a schematic view of the winding of the clamping end of the present invention;

in the figure: the pliers head seat 1, the rotating assembly 2, the first control rope 3, the pliers head assembly 4, the second control rope 5, the tensioning wheel assembly 6, the difference compensation assembly 7, the rotating seat 21, the first rotating wheel 22, the mounting shaft 23, the limiting wheel 24, the left pliers head 41, the right pliers head 42, the second rotating wheel 43, the third rotating wheel 44, the interference prevention step 45, the left control rope 51, the right control rope 52, the first tensioning wheel 61, the second tensioning wheel 62, the third tensioning wheel 63, the wire pressing wheel 71, the difference compensation wheel 72, the operating frame 73, the fixing frame 74, the driving wheel 75, the first limiting surface 76 and the second limiting surface 77.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1 to 4, a difference compensation mechanism applied to a manipulator includes a jaw base 1 and a jaw assembly 4 rotatably connected to the jaw base 1, wherein a second control rope 5 is connected to the jaw assembly 4 and the jaw assembly 4 is rotated by pulling the second control rope 5.

The binding clip assembly 4 is rotatable under the pulling control of the second control cord 5. However, the surgical forceps are often not only provided with the forceps head assembly 4 at a position which is a movable joint, for example, universal rotation of the forceps head assembly 4 needs to be realized, so that the surgical operation is more flexible, the rotating assembly 2 is arranged between the forceps head assembly 4 and the forceps head seat 1, one end of the rotating assembly 2 is rotatably connected with the forceps head seat 1, the other end of the rotating assembly 2 is rotatably connected with the forceps head assembly 4, the rotating direction of the rotating assembly 2 is different from that of the forceps head assembly 4, and the first control rope 3 is connected to the rotating assembly 2 and can rotate the rotating assembly 2 by pulling the first control rope 3. Therefore, the rotation in different directions is realized through the mutual matching of the rotating assembly 2 and the forceps head assembly 4, the multidirectional rotation can be realized in the operation process, the operation is flexible, and the requirements under the complex operation environment can be met.

However, if the second control cord 5 is directly connected to the binding clip assembly 4 through the rotating assembly 2, when the rotating assembly 2 rotates to one side, the side forms a passage with a shorter path, and the second control cord 5 in a free state tends to be connected to the binding clip assembly 4 through the shorter passage, and the second control cord 5 is loosened to be separated from the predetermined track. Therefore, a tensioning wheel assembly 6 for preventing the second control rope 5 from loosening is arranged on the tong head seat 1, and the second control rope 5 is pressed on the tensioning wheel assembly 6.

Although lateral slackening of the second control cord 5 is prevented, it has been found that during use, the jaw assembly 4 is slightly displaced when the rotating assembly 2 is rotated, i.e. the rotation of the two interferes. This is because the length of the second control wire 5 pressed against the tension pulley assembly 6 during the rotation of the rotating assembly 2 becomes long, resulting in the overall tension of the second control wire 5, which causes a slight shift of the jaw assembly 4. Taking fig. 6 as an example, when the rotating assembly 2 rotates downward, the second tensioning wheel 62 rotates along the axis, the third tensioning wheel 63 presses downward, the first tensioning wheel 61 remains stationary, the angle increases, the length of the left control cord 51 wound around the surface of the second tensioning wheel 62 increases, the left control cord 51 is tightened, and the left tong head 41 is affected to rotationally offset the left tong head 41.

Therefore, a difference compensation assembly 7 is additionally arranged, the second control rope 5 is pressed on the surface of the difference compensation assembly 7, and the change trend of the length of the second control rope 5 pressed on the difference compensation assembly 7 is opposite to the change trend of the length of the second control rope 5 pressed on the tension pulley assembly 6 in the rotating process. That is, when the length of the second control rope 5 pressed against the tension pulley assembly 6 is increased so that the second control rope 5 is tightened, the length of the second control rope 5 pressed against the difference value compensating assembly 7 is decreased so that the second control rope 5 is loosened to cancel out the tightening of the second control rope 5 on the tension pulley assembly 6, and vice versa. The event the utility model discloses be equipped with difference compensation subassembly 7, rotate the in-process, the length variation trend that the second control rope 5 pressure was established on difference compensation subassembly 7 is opposite just with take-up pulley subassembly 6, the second control rope 5 is established because of the pressure and is being tightened or lax that 6 surface length changes of take-up pulley subassembly lead to and all can compensate by difference compensation subassembly 7 and offset like this to prevent that second control rope 5 from influencing binding clip subassembly 4's position because of the change of tight degree, guarantee binding clip subassembly 4 by independent control.

Specifically, the difference compensation assembly 7 comprises an operation frame 73 and a fixed frame 74 which are connected in a rotating mode, the operation frame 73 is provided with a wire pressing wheel 71 and a difference compensation wheel 72, the axis of the difference compensation wheel 72 coincides with the rotating axis of the operation frame 73 rotating relative to the fixed frame 74, the second control rope 5 is sequentially arranged at the upper end of the wire pressing wheel 71 and the lower end of the difference compensation wheel 72 in a pressing mode, or the second control rope 5 is sequentially arranged at the lower end of the wire pressing wheel 71 and the upper end of the difference compensation wheel 72 in a pressing mode. And the driving wheel 75 is coaxially arranged with the difference value compensation wheel 72, and one end of the first control rope 3 far away from the rotating assembly 2 is fixedly connected to the driving wheel 75.

When the manual control operating frame 73 is used, the manual control operating frame is controlled to rotate upwards or downwards, and the rotating assembly 2 is driven by the first control rope 3 to rotate upwards or downwards. The creasing wheel 71 is raised or depressed so that the length of the second control cord 5 pressed against the difference compensating wheel 72 increases or decreases.

Referring to fig. 5 and 6, the rotating assembly 2 includes a rotating seat 21, one end of the rotating seat 21 is provided with a first rotating wheel 22, the first rotating wheel 22 is rotatably connected with the bit holder 1, the first control rope 3 is connected to the first rotating wheel 22 and pulls the first control rope 3 to drive the first rotating wheel 22 to rotate, and one end of the rotating seat 21, which is far away from the first rotating wheel 22, is rotatably connected with the bit assembly 4. Pulling the first control rope 3, the first control rope 3 drives the first rotating wheel 22 to rotate the rotating seat 21.

The first control rope 3 and the rotating assembly 2, and the second control rope 5 and the binding clip assembly 4 are connected with each other in a manner that the control ropes are fixedly connected to a fixed block (not shown in the figure) firstly, and then the fixed block is fixedly connected to the rotating wheel.

Preferably, the rotating base 21 is further fixedly connected with a mounting shaft 23, the limiting wheel 24 is sleeved on the mounting shaft 23 and is rotatably connected with the mounting shaft 23, and the second control rope 5 is pressed on the limiting wheel 24. In order to ensure that the binding clip can rotate in two directions, the control rope should be connected to the fixed block in two directions, so that the control rope needs to be wound onto the rotating wheel from different directions, the connection relationship between the right control rope 52 and the third rotating wheel 44 in fig. 2 can be combined, the right control rope 52 can be bent into two parallel lines by pulling the third rotating wheel 44 from two directions, but when approaching the third rotating wheel 44, the right control rope 52 is connected to the fixed block (not shown in the figure, but is a lug fixedly connected to the third rotating wheel 44) from two directions, the two parallel lines at the tail end can gradually extend out an angle and cannot be kept parallel, after the limiting wheel 24 is arranged, the right control rope 52 is pressed on the limiting wheel 24, so that the limiting wheel 24 plays a role in limiting and contracting on the right control rope 52, so that the distance between the two lines can be kept parallel is longer, when in use, the control is more stable.

Referring to fig. 5 and 6, the binding clip assembly 4 includes a left binding clip 41 and a right binding clip 42, a second rotating wheel 43 is disposed at an end of the left binding clip 41 close to the rotating assembly 2, the second rotating wheel 43 is rotatably connected to the rotating assembly 2, a third rotating wheel 44 is disposed at an end of the right binding clip 42 close to the rotating assembly 2, the third rotating wheel 44 is rotatably connected to the rotating assembly 2, the second control rope 5 is connected to the second rotating wheel 43 and the third rotating wheel 44, and pulling the second control rope 5 can rotate the second rotating wheel 43 and/or the third rotating wheel 44.

Preferably, the second control cord 5 includes a left control cord 51 connected to the second turning wheel 43 and a right control cord 52 connected to the third turning wheel 44. The left control rope 51 and the right control rope 52 are controlled independently, so that the left binding clip 41 and the right binding clip 42 can rotate independently, and the user can operate and control the forceps conveniently.

Preferably, the outer edge of the second rotating wheel 43 and/or the third rotating wheel 44 is extended with an interference prevention step 45. In this way, the left control rope 51 connected to the second rotatable wheel 43 and the right control rope 52 connected to the third rotatable wheel 44 can be separated from each other by the interference prevention step 45 during use, thereby preventing the left control rope 51 and the right control rope 52 from being worn due to mutual friction during use.

As shown in fig. 5 and 6, the tensioning wheel assembly 6 includes a first tensioning wheel 61, a second tensioning wheel 62, and a third tensioning wheel 63, which are sequentially disposed, the first tensioning wheel 61 is connected to the holder 1, the second tensioning wheel 62 and the third tensioning wheel 63 are connected to the rotating assembly 2, two first tensioning wheels 61, two second tensioning wheels 62, and two third tensioning wheels 63 are disposed and respectively correspond to the left control rope 51 and the right control rope 52, the left control rope 51 is sequentially pressed at a lower end of the first tensioning wheel 61, an upper end of the second tensioning wheel 62, and a lower end of the third tensioning wheel 63, and the right control rope 52 is sequentially pressed at an upper end of the first tensioning wheel 61, a lower end of the second tensioning wheel 62, and an upper end of the third tensioning wheel 63. Similarly, two of the tension roller 71 and the difference compensating pulley 72 are provided, corresponding to the left control rope 51 and the right control rope 52, respectively.

Preferably, the axis of the second tension pulley 62 coincides with the rotation axis of the rotating assembly 2. That is, the axis of the second tension pulley 62 coincides with the axis of the first rotation wheel 22.

As shown in fig. 4 and 5, the length of the second control rope 5 pressed against the difference-compensating sheave 72 and the second tension sheave 62 is constant. Therefore, the difference can be completely filled, and the ideal state that the rotation of the tong head assembly 4 and the rotation assembly 2 is completely not interfered is realized.

Referring to fig. 2 and 4, a first limiting surface 76 is disposed on the operating frame 73, a second limiting surface 77 is disposed on the fixing frame 74, the operating frame 73 is rotated to enable the first limiting surface 76 to be pressed on the second limiting surface 77, an included angle between the first limiting surface 76 and the second limiting surface 77 is 20-45 degrees, and the diameter of the difference compensation wheel 72 is 2-4.5 times that of the second tensioning wheel 62. Preferably, the angle between the first and second limiting surfaces 76 and 77 is 30 degrees, the diameter of the difference compensation wheel 72 is 3 times the diameter of the second tension wheel 62, and the diameter of the driving wheel 75 is 3 times the diameter of the first rotation wheel 22. Thus, the rotation of the operating frame 73 within the range of 30 degrees just can drive the rotating assembly 2 to rotate within the range of 90 degrees, and the tight state of the second control rope 5 is not changed in any way during the rotation of the rotating assembly 2.

The utility model discloses a theory of operation is: during the use, rotate handling frame 73 and drive wheel 75, thereby drive wheel 75 stimulates first control rope 3 and drives first rotation wheel 22 for it rotates to rotate seat 21, because binding clip subassembly 4 is connected in the one end of rotating seat 21, so when rotating seat 21 and rotating, binding clip subassembly 4 can wholly follow and rotate seat 21 and move, still can drive second rotation wheel 43 through pulling left control rope 51 in addition, make left binding clip 41 take place to rotate, drive third rotation wheel 44 through pulling right control rope 52, make right binding clip 42 take place to rotate. In the process of rotating the rotating seat 21, the tension or the slack of the second control rope 5 on the surface of the second tension wheel 62 caused by the change of the winding length is offset by the reverse change of the winding length of the second control rope 5 on the surface of the difference compensation wheel 72, so that the tightness of the second control rope 5 is ensured not to change in the whole process. The event the utility model discloses be equipped with difference compensation subassembly 7, rotate the in-process, the length variation trend that the second control rope 5 pressure was established on difference compensation subassembly 7 is opposite just with take-up pulley subassembly 6, the second control rope 5 is established because of the pressure and is being tightened or lax that 6 surface length changes of take-up pulley subassembly lead to and all can compensate by difference compensation subassembly 7 and offset like this to prevent that second control rope 5 from influencing binding clip subassembly 4's position because of the change of tight degree, guarantee binding clip subassembly 4 by independent control.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Although the terms of the nipper base 1, the rotating assembly 2, the first control rope 3, the nipper head assembly 4, the second control rope 5, the tensioning wheel assembly 6, the difference compensating assembly 7, the rotating base 21, the first rotating wheel 22, the mounting shaft 23, the limiting wheel 24, the left nipper head 41, the right nipper head 42, the second rotating wheel 43, the third rotating wheel 44, the interference preventing step 45, the left control rope 51, the right control rope 52, the first tensioning wheel 61, the second tensioning wheel 62, the third tensioning wheel 63, the wire pressing wheel 71, the difference compensating wheel 72, the operation frame 73, the fixing frame 74, the driving wheel 75, the first limiting surface 76, the second limiting surface 77, and the like are used more frequently, the possibility of using other terms is not excluded. These terms are used merely to more conveniently describe and explain the nature of the present invention; they are to be construed in a manner that is inconsistent with the spirit of the invention.

Claims (10)

1. The utility model provides a be applied to difference compensation mechanism of manipulator, includes tong head seat (1) and rotates tong head subassembly (4) of being connected with tong head seat (1), and second control rope (5) are connected on tong head subassembly (4) and pull second control rope (5) and can make tong head subassembly (4) take place to rotate its characterized in that: the pliers head seat (1) is provided with a tensioning wheel assembly (6) used for preventing the second control rope (5) from loosening, the second control rope (5) is arranged on the tensioning wheel assembly (6) in a pressing mode, the pliers head seat further comprises a difference compensation assembly (7), the second control rope (5) is arranged on the surface of the difference compensation assembly (7) in a pressing mode, in the rotating process, the changing trend of the length of the second control rope (5) arranged on the difference compensation assembly (7) in a pressing mode is opposite to the changing trend of the length of the second control rope (5) arranged on the tensioning wheel assembly (6) in a pressing mode, and the rotating angle range of the pliers head assembly (4) is larger than 135 degrees.

2. A difference compensating mechanism applied to a robot as claimed in claim 1, wherein: difference value compensation subassembly (7) are including rotating operation frame (73) and mount (74) of connecting, be equipped with fabric wheel (71) and difference value compensation wheel (72) on operation frame (73), the axial lead of difference value compensation wheel (72) coincides mutually with relative mount (74) pivoted axis of rotation of operation frame (73), second control rope (5) are pressed in proper order and are established the upper end of fabric wheel (71) and the lower extreme of difference value compensation wheel (72), or second control rope (5) are pressed in proper order and are established the lower extreme of fabric wheel (71) and the upper end of difference value compensation wheel (72).

3. A difference compensating mechanism applied to a robot as claimed in claim 2, wherein: be equipped with runner assembly (2) between binding clip subassembly (4) and binding clip seat (1), runner assembly (2) one end is rotated with binding clip seat (1) and is connected, and the other end rotates with binding clip subassembly (4) and is connected, and the direction of rotation of runner assembly (2) is inequality with the direction of rotation of binding clip subassembly (4), and first control rope (3) are connected on runner assembly (2) and rotate handling frame (73) and can stimulate first control rope (3) and make runner assembly (2) take place to rotate.

4. A difference compensating mechanism applied to a robot as claimed in claim 3, wherein: the device is characterized by further comprising a driving wheel (75) which is coaxial with the difference compensation wheel (72), and one end, far away from the rotating assembly (2), of the first control rope (3) is fixedly connected to the driving wheel (75).

5. A difference compensating mechanism applied to a robot as claimed in claim 3, wherein: the tensioning wheel assembly (6) comprises a first tensioning wheel (61), a second tensioning wheel (62) and a third tensioning wheel (63) which are sequentially arranged, the first tensioning wheel (61) is connected to the pliers seat (1), the second tensioning wheel (62) and the third tensioning wheel (63) are connected to the rotating assembly (2), the second control rope (5) comprises a left control rope (51) and a right control rope (52), the first tensioning wheel (61), the second tensioning wheel (62), the third tensioning wheel (63), the wire pressing wheel (71) and the difference compensation wheel (72) are respectively provided with two control ropes (51) and two control ropes (52) which respectively correspond to the left control rope (51) and the right control rope (52), and the left control rope (51) is sequentially arranged at the upper end of the wire pressing wheel (71), the lower end of the difference compensation wheel (72), the lower end of the first tensioning wheel (61), the upper end of the second tensioning wheel (62) and the lower end of the third tensioning wheel (63), the right control rope (52) is sequentially pressed at the lower end of the wire pressing wheel (71), the upper end of the difference compensation wheel (72), the upper end of the first tensioning wheel (61), the lower end of the second tensioning wheel (62) and the upper end of the third tensioning wheel (63).

6. A difference compensating mechanism applied to a robot as claimed in claim 5, wherein: the length of the second control rope (5) pressed on the difference compensation wheel (72) and the second tension wheel (62) is a fixed value.

7. A difference compensating mechanism applied to a robot as claimed in claim 5, wherein: the operating frame (73) is provided with a first limiting surface (76), the fixing frame (74) is provided with a second limiting surface (77), the operating frame (73) is rotated to enable the first limiting surface (76) to be pressed on the second limiting surface (77), an included angle between the first limiting surface (76) and the second limiting surface (77) is 20-45 degrees, and the diameter of the difference compensation wheel (72) is 2-4.5 times of that of the second tensioning wheel (62).

8. A difference compensating mechanism applied to a robot as claimed in claim 2, wherein: rotating assembly (2) are including rotating seat (21), the one end of rotating seat (21) is equipped with first rotation wheel (22), first rotation wheel (22) rotate with tong seat (1) and be connected, first control rope (3) are connected on first rotation wheel (22) and the first control rope (3) of pulling can drive first rotation wheel (22) and take place to rotate, rotate the one end that first rotation wheel (22) were kept away from in seat (21) and rotate with tong head subassembly (4) and be connected, it still fixedly connected with installation axle (23) to rotate on seat (21), and spacing wheel (24) cover is established on installation axle (23) and is rotated with installation axle (23) and be connected, second control rope (5) are pressed and are established on spacing wheel (24).

9. A difference compensating mechanism applied to a robot as claimed in claim 1, wherein: the forceps head assembly (4) comprises a left forceps head (41) and a right forceps head (42), a second rotating wheel (43) is arranged at one end of the left tong head (41) close to the rotating component (2), the second rotating wheel (43) is rotationally connected with the rotating component (2), one end of the right tong head (42) close to the rotating component (2) is provided with a third rotating wheel (44), the third rotating wheel (44) is rotationally connected with the rotating assembly (2), the second control rope (5) is connected with the second rotating wheel (43) and the third rotating wheel (44), and pulling the second control rope (5) can make the second rotating wheel (43) and/or the third rotating wheel (44) rotate, the second control rope (5) comprises a left control rope (51) connected to the second turning wheel (43) and a right control rope (52) connected to the third turning wheel (44).

10. A difference compensating mechanism applied to a robot as claimed in claim 9, wherein: an anti-interference step (45) extends from the outer edge of the second rotating wheel (43) and/or the third rotating wheel (44).

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