Clamp
Technical Field
The invention belongs to the technical field of clamps, and particularly relates to a clamp.
Background
The jig refers to a jig used for machining a workpiece in machining.
For processing a workpiece with a cylindrical structure, in mechanical processing, a traditional triangular chuck is generally adopted to clamp an inner circle or an outer circle of the workpiece; however, for a workpiece with a small thickness, no matter the workpiece is clamped by an outer circle or an inner circle, the workpiece can be damaged by clamping under the condition that the clamping force is not controlled properly; the attractive appearance and the later-stage work are influenced, but if the clamping force is reduced for preventing the workpiece from being clamped, the workpiece can fall off in the high-speed movement process, and the machine or the working personnel are accidentally injured.
The prior art can adopt a layer of gasket with equal thickness on the inner circle or the outer circle of a workpiece, but the phenomenon of workpiece slipping is easily caused on one hand due to friction, and on the other hand, if the gasket is worn, the axis of the workpiece and the axis of a clamp are dislocated, so that the processing precision is influenced.
The present invention is directed to a clamp that solves the above problems.
Disclosure of Invention
In order to solve the above defects in the prior art, the invention discloses a clamp, which is realized by adopting the following technical scheme.
A clamp, characterized by: the clamp comprises an intermediate clamp and an execution clamp, wherein the execution clamp is connected with an inherent clamp on a machine tool through the intermediate clamp.
The execution clamp comprises an execution clamp shell and claw mechanisms, wherein the three claw mechanisms which are uniformly distributed in the circumferential direction are arranged at the front end of the execution clamp shell in a sliding mode; the three first racks are fixedly arranged on the three claw mechanisms respectively and are meshed with a fourth gear in the execution clamp shell respectively; and the execution clamp shell is also provided with a fastening mechanism for locking the fourth gear.
The claw mechanism comprises a first gear, a second gear, a telescopic driving shaft, a first support, a third gear, an inner clamping plate, an outer clamping plate, a second rack, a third rack, a fixed shaft, a second support, an installation shell and guide plates, wherein one end of the installation shell is provided with two square openings, the other end of the installation shell is provided with a shaft hole, and the inner end face of one end of the installation shell, which is provided with the shaft hole, is fixedly provided with the two guide plates; one end of the mounting shell provided with the shaft hole is slidably mounted at the front end of the execution clamp shell; the second rack and the third rack are slidably mounted on the mounting shell through two square openings formed in the mounting shell, and the second rack and the third rack are guided by a sliding cavity formed by two guide plates and two inner side surfaces of the mounting shell; one end of the outer clamping plate is fixedly arranged at one end of the second rack positioned on the outer side of the mounting shell, one end of the inner clamping plate is fixedly arranged at one end of the third rack positioned on the outer side of the mounting shell, and a sliding space is formed between the inner clamping plate and the outer clamping plate; the first gear is rotatably arranged in the mounting shell through the fixed shaft, is respectively meshed with the second rack and the third rack, and is positioned between the third rack and the second rack; the telescopic driving shaft consists of a telescopic inner rod and a telescopic outer sleeve, one end of the telescopic inner rod is rotatably arranged in the mounting shell through a second support, the other end of the telescopic inner rod is nested and arranged at the inner side of one end of the telescopic outer sleeve, the other end of the telescopic outer sleeve penetrates through a shaft hole formed in the mounting shell and is rotatably arranged in the execution clamp shell through a first support, a second gear is fixedly arranged on the telescopic inner rod, and the second gear is meshed with the first gear; the third gear is fixedly arranged on the telescopic outer sleeve.
The installation rotating shaft is rotatably arranged in the execution clamp shell, the fluted disc is fixedly arranged at one end of the installation rotating shaft, and the fluted disc is respectively meshed with three third gears in the three claw mechanisms; the worm wheel is arranged at the other end of the installation rotating shaft, the two worms are symmetrically arranged in the execution clamp shell and are respectively meshed with the worm wheel and synchronously connected with the two worms through a synchronous mechanism.
As a further improvement of the present technology, one end of the middle clamp has a hexagonal nesting column, one end of the execution clamp housing has a hexagonal nesting groove, three fastening threaded holes are circumferentially and uniformly formed on the inner wall surface of the hexagonal nesting groove, the middle clamp is connected with the execution clamp housing through the nesting fit of the hexagonal nesting column and the hexagonal nesting groove, and the middle clamp and the execution clamp housing are fixed through the fit of the three fastening screws and the three fastening threaded holes.
As a further improvement of the technology, a first mounting groove is formed in the execution fixture, two groups of mounting round holes are formed in the inner wall surface of the first mounting groove, and one end of each group of mounting round holes penetrates out of the outer side of the execution fixture shell; the two sides of the first mounting groove, on which the mounting round hole is formed, are respectively provided with a fourth mounting groove.
One ends of the two worms are respectively and rotatably arranged in the two groups of mounting round holes which do not penetrate through the outside of the executing clamp shell, the other ends of the two worms penetrate through the mounting round holes which penetrate through the inside and the outside of the executing clamp shell, and the end surfaces of the two worms are provided with hexagonal grooves;
the synchronous mechanism comprises a first synchronous gear, a second synchronous gear and a third synchronous gear, wherein two first synchronous wheels are respectively arranged at two ends of one of the two worms, two third synchronous wheels are respectively arranged at two ends of the other of the two worms, and the two first synchronous wheels and the two third synchronous wheels are respectively in meshed transmission connection through the three second synchronous wheels; the first synchronizing wheel, the second synchronizing wheel and the third synchronizing wheel are respectively positioned in two fourth mounting grooves formed in the execution fixture.
As a further improvement of the technology, a third mounting groove is formed in the execution fixture, three mounting sliding grooves are uniformly formed in the inner circular surface of the third mounting groove in the circumferential direction, and two guide grooves are formed in two side surfaces of each mounting sliding groove; two sides of one end, provided with the shaft hole, of the three mounting shells are respectively provided with a guide block, and the three mounting shells are respectively arranged on the execution clamp shell through the matching of the two guide blocks and the guide grooves on the three mounting shells.
As a further improvement of the technology, a second mounting groove is formed in the execution clamp shell, and the second mounting groove is communicated with the first mounting groove and the third mounting groove; three circular holes are uniformly formed in the inner circular surface of the second mounting groove in the circumferential direction, and three mounting circular grooves penetrating through the execution clamp shell are formed in one ends of the three circular holes; the third gear is rotatably arranged on the mounting rotating shaft, the three first racks are fixedly arranged on the three mounting shells through a connecting plate respectively, and the three first racks are meshed with the third gear respectively; the fastening sleeve is rotatably arranged on the mounting rotating shaft and is fixed with the end face of the fourth gear; the three fastening mechanisms are circumferentially and uniformly arranged on the execution clamp.
The fastening mechanism comprises an upper fastening rod, a sliding threaded sleeve and a support ring, wherein internal threads are arranged on the inner circular surface of the support ring, the support ring is fixedly arranged in the execution clamp shell, external threads are arranged on the outer circular surface of the sliding threaded sleeve, the sliding threaded sleeve is arranged on the support ring through threaded fit, and one end of the sliding threaded sleeve is matched with the outer circular surface of the fastening sleeve; one end of the upper tightening rod is provided with a hexagonal groove which is convenient to drive, and the other end of the upper tightening rod is slidably arranged in the sliding threaded sleeve through the matching of the guide block and the guide groove; and one end of the tightening rod with the hexagonal groove penetrates through the corresponding circular hole and the mounting circular groove.
The end face of the second mounting groove is provided with an annular T-shaped guide groove, one end of the gear ring is provided with a T-shaped guide block, the gear ring is mounted in the execution clamp shell through the rotary fit of the T-shaped guide block and the T-shaped guide groove, the three fifth gears are mounted on the tightening rods in the three fastening mechanisms respectively, and the three fifth gears are meshed with the gear ring respectively.
Compared with the traditional clamp technology, the clamp has the following beneficial effects:
1. the clamp designed by the invention can be suitable for cylindrical workpieces with thinner thickness, the inner wall and the outer wall of the workpiece are simultaneously fixed by the three inner clamping plates and the three outer clamping plates in the use process, so that the fastening effect can be improved, the clamping force of the clamp on the workpiece can be relatively reduced under the condition of the same fastening effect, and the condition that the workpiece is damaged by clamping is prevented to a certain extent.
2. The two worms are designed, so that the gravity center of the clamp is always positioned on the middle axis, eccentric motion cannot occur in the use process, and any one of the two worms can be driven in the clamping process; and the invention also designs a synchronous mechanism which ensures that when one of the two worms rotates, the other one of the two worms also rotates simultaneously, and the normal rotation of the worm wheel cannot be influenced by the self-locking function of the worm wheel and the worm.
3. According to the invention, three fastening mechanisms are designed, and after the three mounting shells are fixed relative to the position of the execution clamp shell, the three mounting shells play a role in fixing and limiting, so that the stability of clamping a workpiece by the clamp is ensured.
4. The clamping device clamps a cylindrical structure, finishes clamping a workpiece by adjusting the claw mechanism, automatically adapts to the size of the workpiece by the free synchronous sliding of the claw mechanism in the clamping process, locks the synchronous sliding of the claw mechanism after finishing clamping the workpiece, and finally finishes the clamping state. From the above, the present invention has an effect of simple operation.
Drawings
Fig. 1 is an external view of an entire part.
Fig. 2 is a schematic view of the overall component distribution.
FIG. 3 is a schematic view of the intermediate clamp and the performing clamp installation.
Fig. 4 is an external view of the housing of the actuating jig.
Fig. 5 is a schematic view of the housing structure of the actuating jig.
Fig. 6 is a schematic view of the intermediate clamp and the performing clamp cooperating.
Fig. 7 is a schematic view of a worm installation.
Fig. 8 is a schematic view of the fastening mechanism installation.
Fig. 9 is a schematic view of the jaw mechanism installation.
Fig. 10 is a schematic view of the internal structure of the execution jig.
Fig. 11 is a fastening mechanism synchronization diagram.
Fig. 12 is a schematic view of a ring gear structure.
Fig. 13 is a schematic view of the fastening mechanism.
Fig. 14 is a synchronization diagram of the jaw mechanism.
Fig. 15 is a schematic view of the jaw mechanism adjustment.
Fig. 16 is a worm synchronization diagram.
Fig. 17 is an external view of the claw mechanism.
Fig. 18 is a schematic view of the structure of the mounting case.
Fig. 19 is a schematic view of the claw mechanism.
Fig. 20 is a schematic view of the second rack, the third rack and the first gear in cooperation.
Fig. 21 is a schematic view of a telescopic drive shaft structure.
Number designation in the figures: 1. an intermediate clamp; 2. executing the clamp; 3. fastening screws; 4. an execution fixture housing; 5. a hexagonal nesting groove; 6. a first mounting groove; 7. a second mounting groove; 8. a third mounting groove; 9. fastening the threaded hole; 10. a fourth mounting groove; 11. a guide plate; 12. mounting a round hole; 13. a circular hole; 14. installing a circular groove; 15. installing a chute; 16. a guide groove; 17. a hexagonal nested column; 18. a worm; 19. a worm gear; 20. a synchronization mechanism; 22. a fastening mechanism; 23. fastening sleeves; 24. a T-shaped chute; 25. a first gear; 26. a second gear; 27. a claw mechanism; 28. a telescopic drive shaft; 29. a first support; 30. a third gear; 31. a fluted disc; 32. a fourth gear; 33. a ring gear; 34. tightening the rod; 35. a fifth gear; 36. sliding the threaded sleeve; 37. a T-shaped slider; 38. a support ring; 39. mounting a shell; 40. a connecting plate; 41. a first rack; 42. a first synchronizing gear; 43. a second synchronizing gear; 44. a third synchronizing gear; 45. an inner splint; 46. an outer splint; 47. a guide block; 48. a square opening; 49. a shaft hole; 50. installing a rotating shaft; 51. a second support; 52. a second rack; 53. a third rack; 54. a fixed shaft; 55. a telescopic inner rod; 56. a telescopic jacket.
Detailed Description
The following detailed description of embodiments of the present invention is provided in connection with the accompanying drawings and examples. The following examples or figures are illustrative of the present invention and are not intended to limit the scope of the present invention.
As shown in fig. 1, it comprises an intermediate clamp 1, an implement clamp 2, wherein the implement clamp 2 is connected with an inherent clamp on a machine tool through the intermediate clamp 1.
As shown in fig. 1, 2 and 3, the execution fixture 2 comprises an execution fixture housing 4 and a jaw mechanism 27, wherein as shown in fig. 10, three jaw mechanisms 27 which are uniformly distributed in the circumferential direction are slidably mounted at the front end of the execution fixture 2 housing; the three first racks 41 are respectively and fixedly arranged on the three claw mechanisms 27, and the three first racks 41 are respectively meshed with the fourth gear 32 in the execution clamp shell 4; the actuating clamp housing 4 is also fitted with a fastening mechanism 22 that deadlocks the fourth gear 32.
As shown in fig. 17 and 19, the claw mechanism 27 includes a first gear 25, a second gear 26, a telescopic driving shaft 28, a first support 29, a third gear 30, an inner clamp plate 45, an outer clamp plate 46, a second rack 52, a third rack 53, a fixed shaft 54, a second support 51, a mounting shell 39, and guide plates 11, wherein as shown in fig. 18, two square openings 48 are formed at one end of the mounting shell 39, a shaft hole 49 is formed at the other end of the mounting shell 39, and as shown in fig. 19, two guide plates 11 are fixedly mounted on an inner end surface of one end of the mounting shell 39, at which the shaft hole 49 is formed; one end of the mounting shell 39 provided with the shaft hole 49 is slidably mounted at the front end of the execution clamp shell 4; the second rack 52 and the third rack 53 are slidably mounted on the mounting shell 39 through two square openings 48 formed in the mounting shell 39, and the second rack 52 and the third rack 53 are guided by a sliding cavity formed by the two guide plates 11 and two inner side surfaces of the mounting shell 39; as shown in fig. 20, one end of the outer clamp plate 46 is fixedly mounted on one end of the second rack 52 located outside the mounting shell 39, one end of the inner clamp plate 45 is fixedly mounted on one end of the third rack 53 located outside the mounting shell 39, and a sliding space is formed between the inner clamp plate 45 and the outer clamp plate 46; the first gear 25 is rotatably mounted in the mounting shell 39 by a fixed shaft 54, and the first gear 25 is respectively engaged with the second rack 52 and the third rack 53; the first gear 25 is located between the third rack 53 and the second rack 52; as shown in fig. 21, the telescopic driving shaft 28 is composed of a telescopic inner rod 55 and a telescopic outer sleeve 56, one end of the telescopic inner rod 55 is rotatably installed in the installation shell 39 through a second support 51, the other end of the telescopic inner rod 55 is nested inside one end of the telescopic outer sleeve 56, the other end of the telescopic outer sleeve 56 passes through a shaft hole 49 formed in the installation shell 39 and is rotatably installed in the execution clamp shell 4 through a first support 29, a second gear 26 is fixedly installed on the telescopic inner rod 55, and as shown in fig. 19, the second gear 26 is meshed with the first gear 25; the third gear 30 is fixedly mounted to the telescoping outer sleeve 56.
As shown in fig. 3, the mounting shaft 50 is rotatably mounted in the actuating clamp housing 4, and as shown in fig. 15, the toothed disc 31 is fixedly mounted at one end of the mounting shaft 50, and the toothed disc 31 is engaged with the three third gears 30 of the three pawl mechanisms 27; a worm wheel 19 is arranged at the other end of the installation rotating shaft 50, and as shown in fig. 7, two worms 18 are symmetrically arranged in the execution clamp shell 4 and are respectively meshed with the worm wheel 19; the two worms 18 are synchronously connected by a synchronization mechanism 20.
The two worms 18 are designed to ensure that the center of gravity of the clamp is always positioned on the middle axis, and eccentric motion cannot occur in the use process. It is possible to drive either one of the two worm screws 18 during clamping.
The synchronization mechanism 20 designed in the invention has the function of ensuring that when one of the two worms 18 rotates, the other worm rotates simultaneously, and the normal rotation of the worm wheel 19 cannot be influenced by the self-locking function of the worm wheel 19 and the worm 18.
As shown in fig. 6, one end of the middle clamp 1 has a hexagonal nesting column 17, as shown in fig. 4 and 5, one end of the execution clamp housing 4 has a hexagonal nesting groove 5, and the inner wall surface of the hexagonal nesting groove 5 is circumferentially and uniformly provided with three fastening threaded holes 9, as shown in fig. 3, the middle clamp 1 is connected with the execution clamp housing 4 through the nesting fit of the hexagonal nesting column 17 and the hexagonal nesting groove 5, and is fixed by the fit of three fastening screws 3 and the three fastening threaded holes 9.
The inherent clamp on the machine tool can drive the middle clamp 1 to rotate in the working process, and the middle clamp 1 rotates to drive the execution clamp 2 to rotate through the matching of the hexagonal nesting column 17 and the hexagonal nesting groove 5.
As shown in fig. 5, a first mounting groove 6 is formed in the execution fixture 2, two sets of mounting circular holes 12 are formed in the inner wall surface of the first mounting groove 6, and one end of each of the two sets of mounting circular holes 12 penetrates through the outer side of the execution fixture housing 4; the two sides of the first mounting groove 6 with the mounting round hole 12 are both provided with a fourth mounting groove 10.
As shown in fig. 7, one ends of the two worms are respectively rotatably mounted in the mounting circular holes which do not penetrate through the outside of the actuating fixture housing in the two sets of mounting circular holes, the other ends of the two worms penetrate through the mounting circular holes which penetrate through the inside and the outside of the actuating fixture housing, and the end surfaces of the two ends are provided with hexagonal grooves; the hexagonal groove is used for facilitating people to drive the worm 18 to rotate through the hexagonal wrench.
As shown in fig. 16, the synchronizing mechanism 20 includes a first synchronizing gear 42, a second synchronizing gear 43, and a third synchronizing gear 44, wherein two first synchronizing gears are respectively installed at two ends of one of the two worms 18, two third synchronizing gears are respectively installed at two ends of the other worm 18 of the two worms 18, and the two first synchronizing gears and the two third synchronizing gears are respectively in meshing transmission connection through the three second synchronizing gears; the first synchronizing wheel, the second synchronizing wheel and the third synchronizing wheel are respectively positioned in two fourth mounting grooves 10 formed in the execution fixture 2.
In the present invention, whichever screw of the two worms 18 rotates drives the other worm 18 to rotate through the first synchronizing gear 42, the second synchronizing gear and the third synchronizing gear. In the invention, the first synchronizing wheel and the third synchronizing wheel are in transmission connection through the three second synchronizing wheels, and the direction of the helical teeth of the two worms 18 designed by the invention is opposite because of the change of the transmission direction.
As shown in fig. 5, a third mounting groove 8 is formed in the execution fixture 2, three mounting sliding grooves 15 are uniformly formed in the inner circumferential surface of the third mounting groove 8 in the circumferential direction, and two side surfaces of each mounting sliding groove 15 are provided with a guide groove 16; as shown in fig. 18, two sides of one end of the three mounting cases 39, which is provided with the shaft holes 49, are respectively provided with a guide block 47, and as shown in fig. 9, the three mounting cases 39 are respectively mounted on the execution fixture housing 4 through the cooperation of the two guide blocks 47 and the guide grooves 16 thereon.
As shown in fig. 5, a second mounting groove 7 is formed in the execution fixture housing 4, and the second mounting groove 7 is communicated with the first mounting groove 6 and the third mounting groove 8; three circular holes 13 are uniformly formed in the inner circular surface of the second mounting groove 7 in the circumferential direction, and three mounting circular grooves 14 penetrating through the execution clamp shell 4 are formed at one ends of the three circular holes 13; as shown in fig. 8 and 14, the fourth gear 32 is rotatably mounted on the mounting rotating shaft 50, as shown in fig. 14, three first racks 41 are respectively fixedly mounted on the three mounting cases 39 through one connecting plate 40, and the three first racks 41 are respectively engaged with the fourth gear 32; as shown in fig. 8, the fastening sleeve 23 is rotatably mounted on the mounting rotating shaft 50, and the fastening sleeve 23 is fixed with the end face of the fourth gear 32; three fastening devices 22 are circumferentially uniformly mounted on the actuating clamp 2.
In the invention, because the mounting shell 39 can slide relative to the execution clamp shell 4 in the adjusting process, the telescopic driving shaft 28 designed by the invention has a telescopic function, and when the mounting shell 39 slides, the mounting shell 39 can drive the corresponding telescopic inner rod 55 to slide relative to the corresponding telescopic outer sleeve 56; the normal sliding of the mounting shell 39 is not affected, and meanwhile, the telescopic inner rod 55 and the telescopic outer sleeve 56 are in sliding fit with the guide grooves through the guide blocks, so that the torque can be transmitted normally.
As shown in fig. 13, the fastening mechanism 22 includes a tightening rod 34, a sliding threaded sleeve 36, a support ring 38, wherein the support ring 38 has an internal thread on an inner circumferential surface thereof, the support ring 38 is fixedly installed in the actuating clamp housing 4, the sliding threaded sleeve 36 has an external thread on an outer circumferential surface thereof, the sliding threaded sleeve 36 is installed on the support ring 38 by screw-fitting, and one end of the sliding threaded sleeve 36 is fitted with an outer circumferential surface of the fastening sleeve 23; one end of the tightening rod 34 is provided with a hexagonal groove which is convenient to drive, and the other end of the tightening rod 34 is slidably arranged in the sliding threaded sleeve 36 through the matching of the guide block and the guide groove; and one end of the tightening rod 34 having a hexagonal groove passes through the corresponding circular hole 13 and the mounting circular groove 14. The hexagonal groove is used for facilitating people to drive the tightening rod 34 to rotate through the hexagonal wrench.
As shown in fig. 8, the end surface of the second mounting groove 7 is opened with a ring-shaped T-shaped guide groove, as shown in fig. 12, one end of the ring gear 33 is mounted with a T-shaped guide block, as shown in fig. 8, the ring gear 33 is mounted in the execution fixture housing 4 by the rotational fit of the T-shaped guide block and the T-shaped guide groove, as shown in fig. 11, three fifth gears 35 are respectively mounted on the tightening rods 34 in the three fastening mechanisms 22, and the three fifth gears 35 are respectively engaged with the ring gear 33.
The synchronism of the three fastening mechanisms 22 is ensured through the matching of the gear ring 33 and the three fifth gears 35, and when the fastening sleeve 23 is tightened or loosened, only one tightening rod 34 needs to be rotationally adjusted, so that the operation is convenient.
The clamp designed by the invention can be selected to be different in size according to the actual size of the tool.
The specific working process is as follows: when using the jig designed by the present invention, the intermediate jig 1 is first mounted on the inherent jig on the machine tool, and then the execution jig 2 is mounted on the intermediate jig 1 by the fitting of the hexagonal nesting columns 17 and the hexagonal nesting grooves 5, and is fixed by tightening the screws.
Then, the workpiece is installed, and when the workpiece is installed, in order to adapt to the inner diameter and the outer diameter of the workpiece, the installation shells 39 in the three jaw mechanisms 27 need to be manually adjusted, so that the workpiece is nested between the inner clamping plates 45 and the outer clamping plates 46 on the three jaw mechanisms 27; in the adjusting process, when one of the mounting shells 39 slides along the radial direction of the actuating fixture housing 4, the mounting shell 39 can drive the first rack 41 mounted thereon to slide through the corresponding connecting plate 40, the first rack 41 can drive the fourth gear 32 to rotate, the fourth gear 32 rotates to drive the other two first racks 41 to slide, and then the other two mounting shells 39 are driven to slide, that is, the three claw mechanisms 27 keep synchronous sliding in the adjusting process, so that the fixture can clamp workpieces in a centering manner, and the stability in the processing process is improved; then, when the worm 18 is driven to rotate, the worm wheel 19 drives the worm 18 to rotate, and the worm 18 drives the fluted disc 31 to rotate; when the fluted disc 31 is driven to rotate, the fluted disc 31 can drive the three third gears 30 to rotate, the three third gears 30 drive the three telescopic driving shafts 28 to rotate, the three telescopic driving shafts 28 drive the three second gears 26 to rotate, the three second gears 26 drive the three first gears 25 to rotate, the three first gears 25 drive the three second racks 52 and the three third racks 53 to move, the sliding directions of the second racks 52 and the third racks 53 in the same claw mechanism 27 are opposite, and the second racks 52 and the third racks 53 slide to drive the outer clamping plate 46 and the inner clamping plate 45 to slide relatively; further clamping the workpiece; when the inner clamping plate 45 and the outer clamping plate 46 are adjusted to clamp the workpiece, the three mounting shells 39 can continuously slide in order to adapt to the workpiece; when the workpiece is fixed by the three inner and outer clamping plates 45 and 46, the positions of the three mounting cases 39 on the jig housing 4 are also relatively fixed.
After the three mounting shells 39 perform position fixing relative to the clamp housing 4, any one of the tightening rods 34 is rotated, the tightening rod 34 drives the sliding threaded sleeve 36 to rotate through the guide block and the guide groove, and the sliding threaded sleeve 36 is in threaded fit with the support ring 38, so that the sliding threaded sleeve 36 moves relative to the support ring 38 in the rotating process, the fastening sleeve 23 is tightened, the fastening sleeve is in a static state, namely the fourth gear 32 is static, and the three mounting shells 39 are static, so that the stability of clamping a workpiece by the clamp is ensured.
When the workpiece is disassembled, the worm 18 is reversely adjusted, so that the three inner clamping plates 45 and the outer clamping plate 46 are opened, and the workpiece can be taken down. At the time of the next use, the tightening lever 34 is rotated reversely so that the three tightening mechanisms 22 release the restriction of the tightening sleeve 23, and the three claw mechanisms 27 can be freely slidably adjusted in the radial direction of the execution jig housing 4.