阅读说明：本技术 一种陀螺仪稳定结构及使用方法 (Gyroscope stabilizing structure and using method ) 是由 邵冠峰 汤叶飞 于 2021-10-21 设计创作，主要内容包括：本发明公开了一种陀螺仪稳定结构及使用方法,包括加工台,所述加工台的上表面固定安装有连接部,所述加工台的上表面固定设有下料斗,所述加工台的上表面设有稳固组件,所述连接部的表面设有驱动机构,所述连接部的内壁设有分切机构,所述加工台的上表面设有进料机构,与现有的技术相比,通过旋钮手柄,手柄带动双头螺杆转动,双头螺杆带动两组第一导向块相向移动,第一导向块带动弧形夹持板和第一防滑垫垂直方向移动,当两组第一防滑垫的内壁与管状陀螺仪旋转轮胚料的外壁接触并将管状陀螺仪旋转轮胚料夹紧后再停止旋钮手柄,从而方便的完成了待分切管状陀螺仪旋转轮胚料的夹持,进而有效的提高了后续分切管状陀螺仪旋转轮胚料的稳定性。(The invention discloses a gyroscope stabilizing structure and a using method, the gyroscope stabilizing structure comprises a processing table, a connecting part is fixedly arranged on the upper surface of the processing table, a blanking hopper is fixedly arranged on the upper surface of the processing table, a stabilizing assembly is arranged on the upper surface of the processing table, a driving mechanism is arranged on the surface of the connecting part, a cutting mechanism is arranged on the inner wall of the connecting part, and a feeding mechanism is arranged on the upper surface of the processing table. Thereby effectively improving the stability of the rotating wheel blank of the subsequent slitting tubular gyroscope.)

1. A gyroscope stabilization structure comprising a processing table (1), characterized in that: processing platform (1)'s last fixed surface installs connecting portion (12), processing platform (1)'s last fixed surface is equipped with down hopper (13), processing platform (1)'s upper surface is equipped with firm subassembly (2), the surface of connecting portion (12) is equipped with actuating mechanism (3), the inner wall of connecting portion (12) is equipped with cuts mechanism (4), processing platform (1)'s upper surface is equipped with feed mechanism (5).

2. The gyroscope stabilizing structure as claimed in claim 1, wherein the bottom four corners of the processing table (1) are fixedly provided with supporting legs (11), the lower surface of the blanking hopper (13) is fixedly connected with a first supporting rod (14), and one end of the first supporting rod (14) is fixedly connected with the upper surface of the processing table (1).

3. The gyroscope stabilizing structure as claimed in claim 1, wherein the stabilizing assembly (2) comprises a moving plate (21), a sliding block (22) is fixedly connected to the lower surface of the moving plate (21), a sliding rail (23) is fixedly arranged on the upper surface of the processing table (1), the sliding block (22) is slidably connected with the sliding rail (23), a placing cavity (24) is formed in one side of the moving plate (21), a first guide groove (25) is formed in the inner wall of the placing cavity (24), first guide blocks (26) are symmetrically and slidably connected to the inner wall of the first guide groove (25), a double-headed screw (27) is rotatably connected between two groups of the first guide blocks (26) through threads, the double-headed screw (27) is rotatably connected with the moving plate (21), and an arc-shaped clamping plate (29) is fixedly connected to one side of each of the two groups of the first guide blocks (26), the opposite sides of the two groups of arc-shaped clamping plates (29) are mutually contacted, one side of each arc-shaped clamping plate (29) is movably contacted with the inner wall of the placing cavity (24), and one side of each sliding block (22) is fixedly connected with a first connecting rod (292).

4. The gyroscope stabilizing structure as claimed in claim 3, wherein the processing table (1) has a notch (231) formed on the upper surface thereof, the lower surface of the slide rail (23) is fixedly connected with the inner wall of the notch (231), a handle (28) is fixedly connected to one end of the double-threaded screw (27), first anti-slip pads (291) are fixedly mounted on the inner walls of the two sets of arc-shaped clamping plates (29), and opposite sides of the two sets of first anti-slip pads (291) are in contact with each other.

5. The gyroscope stabilizing structure as claimed in claim 1, wherein the driving mechanism (3) comprises a motor (31), the surface of the connecting portion (12) is symmetrically and rotatably connected with a first rotating rod (33), the driving output end of the motor (31) is fixedly connected with one end of a set of first rotating rods (33), one end of each set of first rotating rods (33) is fixedly connected with a synchronizing wheel (34), a synchronizing belt (35) is connected between two sets of synchronizing wheels (34) in a transmission manner, the outer wall of the synchronizing belt (35) is fixedly connected with a second connecting rod (36), the outer wall of the connecting portion (12) is symmetrically provided with second guide grooves (37), the inner walls of the two sets of second guide grooves (37) are slidably connected with second guide blocks (38), and one side of the two sets of second guide blocks (38) is fixedly connected with a U-shaped sliding plate (39), one side of the U-shaped sliding plate (39) is provided with a contact groove (391), one end of the second connecting rod (36) is movably contacted with the inner wall of the contact groove (391), one side of the U-shaped sliding plate (39) is fixedly connected with a third connecting rod (392), and one end of the first rotating rod (33) is fixedly connected with a half-side gear (393).

6. A gyroscopic stabilising structure according to claim 5, wherein the motor (31) has a fixed block (32) fixedly attached to its outer wall, one side of the fixed block (32) being fixedly attached to the inner wall of the connecting portion (12).

7. A gyroscopic stabilization structure according to claim 5, in which the splitting mechanism (4) comprises a third guide block (41), one end of the third connecting rod (392) is fixedly connected with one side of the third guide block (41), third guide grooves (42) are symmetrically formed in the inner wall of the connecting portion (12), the third guide blocks (41) are in sliding connection with the third guide grooves (42), fourth connecting rods (43) are fixedly connected to the opposite sides of the two groups of third guide blocks (41), a splitting machine body (44) is fixedly connected between the two groups of fourth connecting rods (43), the inner wall of the connecting part (12) is symmetrically and fixedly connected with fixing rods (45), an arc-shaped material discharging plate (46) is fixedly connected between the two groups of fixing rods (45), the outer wall of the arc-shaped discharging plate (46) is fixedly connected with the upper surface of the discharging hopper (13).

8. A gyroscopic stabilising structure according to claim 7, wherein the inner walls of the arcuate feed plates (46) are fixedly mounted with second non-slip pads (47).

9. The gyroscope stabilizing structure as claimed in claim 5, wherein the feeding mechanism (5) comprises a toothed plate (51), one end of the first connecting rod (292) is fixedly connected to one side of the toothed plate (51), a clamping groove (52) is formed in the upper surface of the processing table (1), a clamping block (53) is slidably connected to the inner wall of the clamping groove (52), the lower surface of the toothed plate (51) is fixedly connected to the upper surface of the clamping block (53), the surface of the connecting portion (12) is rotatably connected to a second rotating rod (54), one end of the second rotating rod (54) is fixedly connected to a transmission gear (55), the transmission gear (55) is in meshing connection with the toothed plate (51), and the transmission gear (55) is in meshing connection with the half-side gear (393).

10. A stable use method of a gyroscope is characterized by comprising the following steps:

firstly, clamping a blank of a gyroscope rotating wheel

Through the knob handle (28), the handle (28) drives the double-threaded screw (27) to rotate, the double-threaded screw (27) drives the two groups of first guide blocks (26) to move in opposite directions, the first guide blocks (26) drive the arc-shaped clamping plates (29) and the first anti-slip pads (291) to move in the vertical direction, and the knob handle (28) is stopped after the inner walls of the two groups of first anti-slip pads (291) are contacted with the outer wall of the tubular gyroscope rotating wheel blank and clamp the tubular gyroscope rotating wheel blank, so that the clamping of the tubular gyroscope rotating wheel blank to be cut is conveniently completed, and the stability of the tubular gyroscope rotating wheel blank to be cut subsequently is effectively improved;

step two, automatic feeding of gyroscope rotating wheel blank

By starting the motor (31), the motor (31) drives one group of first rotating rods (33) to rotate, one group of first rotating rods (33) drives the other group of first rotating rods (33) to rotate through two groups of synchronous wheels (34) and synchronous belts (35), one group of first rotating rods (33) drives the half-edge gear (393) to rotate, the half-edge gear (393) drives the transmission gear (55) to rotate, the transmission gear (55) drives the toothed plate (51) to move, the toothed plate (51) drives the clamping block (53) to move and drives the sliding block (22) to move through the first connecting rod (292), the sliding block (22) drives the moving plate (21) to move, the moving plate (21) drives the tubular gyroscope rotating wheel blank to move, when the half-edge gear (393) is not meshed with the transmission gear (55), the transmission gear (55) stops rotating, the toothed plate (51) stops moving, and therefore automatic feeding of the tubular gyroscope blank is conveniently completed, the convenience of subsequently cutting the tubular gyroscope rotating wheel blank is effectively improved, and the efficiency of subsequently cutting the tubular gyroscope rotating wheel blank is effectively improved;

step three, cutting gyroscope rotating wheel blanks in batches

By starting the splitting machine body (44), the synchronous belt (35) drives the second connecting rod (36) to move downwards, the second connecting rod (36) drives the U-shaped sliding plate (39) to move downwards, the U-shaped sliding plate (39) drives a group of third guide blocks (41) to move downwards through the third connecting rod (392), the third guide blocks (41) drive the splitting machine body (44) to descend through the fourth connecting rod (43), when a splitting wheel of the descending splitting machine body (44) is in contact with a gyro rotating wheel blank, the gyro rotating wheel blank is cut off, so that one-time splitting of the gyro rotating wheel blank is conveniently completed, because the synchronous belt (35) rotates ceaselessly, the synchronous belt (35) drives the U-shaped sliding plate (39) to ascend and descend in the reciprocating vertical direction through the second connecting rod (36), and then through intermittent meshing of the half-edge gear (393) and the transmission gear (55), make pinion rack (51) intermittent type nature drive tubulose gyroscope swiveling wheel blank intermittent type nature advance to make cutting machine body (44) accomplish the batch of tubulose gyroscope swiveling wheel blank and cut, and then effectual improvement cut the efficiency of gyroscope swiveling wheel blank.

Technical Field

The invention relates to the technical field of gyroscope processing, in particular to a gyroscope stabilizing structure and a using method thereof.

Background

A gyroscope: the gyroscope is a rigid body with uniformly distributed mass and axisymmetric shape, and the geometric symmetry axis is the rotation axis of the gyroscope. The prior art has the following problems when processing a gyroscope rotating wheel:

1. when a gyroscope rotating wheel is machined in the prior art, the blank of the gyroscope rotating wheel is shaken when the blank of the gyroscope rotating wheel is cut due to poor clamping effect, so that the blank of the gyroscope rotating wheel is cut subsequently;

2. most gyroscope manufacturers need to cut gyroscope rotating wheel blanks in batches, in the prior art, the gyroscope rotating wheel blanks cannot be cut while feeding, so that the cutting of the gyroscope rotating wheel blanks is inconvenient and low in cutting efficiency, and therefore a gyroscope stabilizing structure and a gyroscope using method are provided for solving the problems.

Disclosure of Invention

The present invention is directed to a gyroscope stabilizing structure and a method for using the same to solve the above problems.

In order to solve the technical problems, the invention adopts the following technical scheme: the utility model provides a gyroscope stable structure, includes the processing platform, the last fixed surface of processing platform installs connecting portion, the last fixed surface of processing platform is equipped with down the hopper, the upper surface of processing platform is equipped with firm subassembly, the surface of connecting portion is equipped with actuating mechanism, the inner wall of connecting portion is equipped with cuts the mechanism, the upper surface of processing platform is equipped with feed mechanism.

Preferably, the bottom four corners of the processing table are fixedly provided with supporting legs, the lower surface of the discharging hopper is fixedly connected with a first supporting rod, and one end of the first supporting rod is fixedly connected with the upper surface of the processing table.

Preferably, the subassembly that stabilizes is including the movable plate, the lower fixed surface of movable plate is connected with the slider, the last fixed surface of processing platform is equipped with the slide rail, slider and slide rail sliding connection, one side of movable plate has been seted up and has been placed the chamber, the inner wall of placing the chamber has seted up first guide way, the inner wall symmetry sliding connection of first guide way has first guide block, and is two sets of screw thread rotation is connected with double-threaded screw between the first guide block, double-threaded screw and movable plate rotate to be connected, and are two sets of the equal fixedly connected with arc grip block in one side of first guide block, it is two sets of the opposite side of arc grip block is in contact with each other, one side of arc grip block and the inner wall movable contact who places the chamber, one side fixedly connected with head rod of slider.

Preferably, the upper surface of the processing table is provided with a notch, the lower surface of the slide rail is fixedly connected with the inner wall of the notch, one end of the double-headed screw is fixedly connected with a handle, the inner walls of the two groups of arc-shaped clamping plates are fixedly provided with first anti-skid pads, and the opposite sides of the two groups of first anti-skid pads are in mutual contact.

Preferably, the driving mechanism comprises a motor, the surface of the connecting part is symmetrically and rotatably connected with a first rotating rod, the driving output end of the motor is fixedly connected with one end of one group of first rotating rods, one end of each of the two groups of first rotating rods is fixedly connected with a synchronous wheel, a synchronous belt is connected between the two groups of synchronous wheels in a transmission way, the outer wall of the synchronous belt is fixedly connected with a second connecting rod, the outer wall of the connecting part is symmetrically provided with second guide grooves, the inner walls of the two groups of second guide grooves are respectively connected with a second guide block in a sliding way, one side of each group of second guide blocks is fixedly connected with a U-shaped sliding plate, one side of the U-shaped sliding plate is provided with a contact groove, one end of the second connecting rod is movably contacted with the inner wall of the contact groove, one side of the U-shaped sliding plate is fixedly connected with a third connecting rod, and one end of the first rotating rod is fixedly connected with a half-edge gear.

Preferably, the outer wall fixedly connected with fixed block of motor, the inner wall fixed connection of one side and connecting portion of fixed block.

Preferably, the slitting mechanism comprises a third guide block, one end of a third connecting rod is fixedly connected with one side of the third guide block, a third guide groove is formed in the inner wall of the connecting portion in a symmetrical mode, the third guide block is connected with the third guide groove in a sliding mode, the opposite sides of the third guide block are fixedly connected with a fourth connecting rod, the fourth connecting rod is connected with a slitting machine body in a symmetrical mode, fixing rods are fixedly connected with the inner wall of the connecting portion in a symmetrical mode, the fixing rods are connected with arc-shaped material placing plates in a symmetrical mode, the fixing rods are connected with the arc-shaped material placing plates in a symmetrical mode, and the outer wall of each arc-shaped material placing plate is fixedly connected with the upper surface of a lower hopper.

Preferably, a second anti-skid pad is fixedly mounted on the inner wall of the arc-shaped material placing plate.

Preferably, the feeding mechanism includes a toothed plate, one end of the first connecting rod is fixedly connected with one side of the toothed plate, a clamping groove is formed in the upper surface of the machining table, a clamping block is slidably connected to the inner wall of the clamping groove, the lower surface of the toothed plate is fixedly connected with the upper surface of the clamping block, the surface of the connecting portion rotates and is connected with a second rotating rod, a transmission gear is fixedly connected to one end of the second rotating rod, the transmission gear is meshed with the toothed plate, and the transmission gear is meshed with a half gear.

A stable use method of a gyroscope comprises the following steps:

firstly, clamping a blank of a gyroscope rotating wheel

Through the knob handle, the handle drives the double-head screw to rotate, the double-head screw drives the two groups of first guide blocks to move oppositely, the first guide blocks drive the arc-shaped clamping plate and the first anti-slip pads to move in the vertical direction, when the inner walls of the two groups of first anti-slip pads are in contact with the outer wall of the tubular gyroscope rotating wheel blank and clamp the tubular gyroscope rotating wheel blank, the knob handle is stopped, so that the clamping of the tubular gyroscope rotating wheel blank to be cut is conveniently completed, and the stability of the tubular gyroscope rotating wheel blank to be cut subsequently is effectively improved;

step two, automatic feeding of gyroscope rotating wheel blank

When the half gear is not meshed with the transmission gear, the transmission gear stops rotating, and the toothed plate stops moving, so that automatic feeding of the tubular gyroscope rotating wheel blank is conveniently finished, convenience of subsequently cutting the tubular gyroscope rotating wheel blank is effectively improved, and efficiency of subsequently cutting the tubular gyroscope rotating wheel blank is effectively improved;

step three, cutting gyroscope rotating wheel blanks in batches

The splitting machine body is started, the synchronous belt drives the second connecting rod to move downwards, the second connecting rod drives the U-shaped sliding plate to move downwards, the U-shaped sliding plate drives a group of third guide blocks to move downwards through the third connecting rod, the third guide blocks drive the splitting machine body to descend through the fourth connecting rod, when a splitting wheel of the descending splitting machine body is in contact with a blank of a gyroscope rotating wheel, the blank of the gyroscope rotating wheel is cut off, and therefore one-time splitting of the blank of the gyroscope rotating wheel is conveniently completed, due to the fact that the synchronous belt rotates ceaselessly, the synchronous belt drives the U-shaped sliding plate to ascend and descend in the reciprocating vertical direction through the second connecting rod, and then the toothed plate intermittently drives the blank of the tubular gyroscope rotating wheel to intermittently advance through the intermittent meshing of the half-edge gear and the transmission gear, and therefore the splitting machine body completes batch splitting of the blank of the tubular gyroscope, and then the efficiency of cutting gyroscope swiveling wheel stock has effectually been improved.

Compared with the prior art, the invention has the beneficial effects that:

1. through the knob handle, the handle drives the double-head screw to rotate, the double-head screw drives the two groups of first guide blocks to move oppositely, the first guide blocks drive the arc-shaped clamping plate and the first anti-slip pads to move in the vertical direction, when the inner walls of the two groups of first anti-slip pads are in contact with the outer wall of the tubular gyroscope rotating wheel blank and clamp the tubular gyroscope rotating wheel blank, the knob handle is stopped, so that the clamping of the tubular gyroscope rotating wheel blank to be cut is conveniently completed, and the stability of the tubular gyroscope rotating wheel blank to be cut subsequently is effectively improved;

2. when the half gear is not meshed with the transmission gear, the transmission gear stops rotating, and the toothed plate stops moving, so that automatic feeding of the tubular gyroscope rotating wheel blank is conveniently finished, convenience of subsequently cutting the tubular gyroscope rotating wheel blank is effectively improved, and efficiency of subsequently cutting the tubular gyroscope rotating wheel blank is effectively improved;

3. the splitting machine body is started, the synchronous belt drives the second connecting rod to move downwards, the second connecting rod drives the U-shaped sliding plate to move downwards, the U-shaped sliding plate drives a group of third guide blocks to move downwards through the third connecting rod, the third guide blocks drive the splitting machine body to descend through the fourth connecting rod, when a splitting wheel of the descending splitting machine body is in contact with a blank of a gyroscope rotating wheel, the blank of the gyroscope rotating wheel is cut off, and therefore one-time splitting of the blank of the gyroscope rotating wheel is conveniently completed, due to the fact that the synchronous belt rotates ceaselessly, the synchronous belt drives the U-shaped sliding plate to ascend and descend in the reciprocating vertical direction through the second connecting rod, and then the toothed plate intermittently drives the blank of the tubular gyroscope rotating wheel to intermittently advance through the intermittent meshing of the half-edge gear and the transmission gear, and therefore the splitting machine body completes batch splitting of the blank of the tubular gyroscope, and then the efficiency of cutting gyroscope swiveling wheel stock has effectually been improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

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

FIG. 2 is an enlarged view of portion A of FIG. 1 according to the present invention;

FIG. 3 is an enlarged view of portion B of FIG. 1 according to the present invention;

FIG. 4 is another schematic structural view of the present invention;

FIG. 5 is an enlarged view of section C of FIG. 4 according to the present invention;

FIG. 6 is a schematic view of the drive mechanism of the present invention coupled to a slitting mechanism;

FIG. 7 is an enlarged view of portion D of FIG. 6 according to the present invention;

FIG. 8 is a schematic view of the connection of the second connecting rod to the U-shaped sliding plate according to the present invention;

in the figure: 1. a processing table; 11. supporting legs; 12. a connecting portion; 13. feeding a hopper; 14. a first support bar; 2. a stabilizing assembly; 21. moving the plate; 22. a slider; 23. a slide rail; 231. a notch; 24. a placement chamber; 25. a first guide groove; 26. a first guide block; 27. a double-ended screw; 28. a handle; 29. an arc-shaped clamping plate; 291. a first non-slip mat; 292. a first connecting rod; 3. a drive mechanism; 31. a motor; 32. a fixed block; 33. a first rotating lever; 34. a synchronizing wheel; 35. a synchronous belt; 36. a second connecting rod; 37. a second guide groove; 38. a second guide block; 39. a U-shaped sliding plate; 391. a contact groove; 392. a third connecting rod; 393. a half-side gear; 4. a slitting mechanism; 41. a third guide block; 42. a third guide groove; 43. a fourth connecting rod; 44. a splitting machine body; 45. fixing the rod; 46. an arc-shaped material placing plate; 47. a second non-slip mat; 5. a feeding mechanism; 51. a toothed plate; 52. a card slot; 53. a clamping block; 54. a second rotating lever; 55. a transmission gear.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example (b): as shown in FIGS. 1 to 8, the invention provides a gyroscope stabilizing structure, which comprises a processing table 1, wherein supporting legs 11 are fixedly installed at four corners of the bottom end of the processing table 1, the supporting legs 11 can effectively improve the stability of the processing table 1, a connecting part 12 is fixedly installed on the upper surface of the processing table 1, a blanking hopper 13 is fixedly arranged on the upper surface of the processing table 1, the blanking hopper 13 can conveniently realize the discharging of cut gyroscope rotating wheel blanks, a first supporting rod 14 is fixedly connected to the lower surface of the blanking hopper 13, one end of the first supporting rod 14 is fixedly connected with the upper surface of the processing table 1, the first supporting rod 14 can support and fix the blanking hopper 13, a stabilizing component 2 is arranged on the upper surface of the processing table 1, the stabilizing component 2 can clamp the gyroscope rotating wheel blanks to be processed, the stability of the cut gyroscope rotating wheel blanks is improved, and the size deviation of the cut rotating wheels is avoided, the surface of connecting portion 12 is equipped with actuating mechanism 3, and the inner wall of connecting portion 12 is equipped with cuts mechanism 4, and actuating mechanism 3 can control to cut 4 vertical direction reciprocating motion of mechanism, cuts the gyro swiveling wheel stock that mechanism 4 can cut in batches, and the upper surface of processing platform 1 is equipped with feed mechanism 5, and actuating mechanism 3 can drive 5 horizontal direction of feed mechanism and remove to realize the intermittent type nature feeding of gyro swiveling wheel stock.

Further, the stabilizing assembly 2 comprises a moving plate 21, a slider 22 is fixedly connected to the lower surface of the moving plate 21, a slide rail 23 is fixedly arranged on the upper surface of the processing table 1, the slider 22 can drive the moving plate 21 to move along the surface horizontal direction of the slide rail 23, the slider 22 is slidably connected with the slide rail 23, a notch 231 is formed in the upper surface of the processing table 1, the lower surface of the slide rail 23 is fixedly connected with the inner wall of the notch 231, the slide rail 23 can be fixed on the inner wall of the notch 231 by forming the notch 231, a placing cavity 24 is formed in one side of the moving plate 21, a first guide groove 25 is formed in the inner wall of the placing cavity 24, first guide blocks 26 are symmetrically and slidably connected to the inner wall of the first guide groove 25, a double-threaded screw 27 is rotatably connected between the two groups of first guide blocks 26, and the double-threaded screw 27 can drive the two groups of first guide blocks 26 to move in the opposite or opposite directions in the vertical direction, the double-end screw 27 is rotatably connected with the moving plate 21, one end of the double-end screw 27 is fixedly connected with a handle 28, the handle 28 can drive the double-end screw 27 to rotate through a knob handle 28, one side of each of two groups of first guide blocks 26 is fixedly connected with an arc-shaped clamping plate 29, the first guide blocks 26 can drive the arc-shaped clamping plates 29 to move in the vertical direction, the two groups of arc-shaped clamping plates 29 can clamp gyroscope rotating wheel blanks to be cut, opposite sides of the two groups of arc-shaped clamping plates 29 are mutually contacted, one side of each of the arc-shaped clamping plates 29 is movably contacted with the inner wall of the placing cavity 24, the inner walls of the two groups of arc-shaped clamping plates 29 are fixedly provided with first anti-skid pads 291, opposite sides of the two groups of first anti-skid pads 291 are mutually contacted, the first anti-skid pads 291 can avoid the gyroscope rotating wheel blanks clamped by the two groups of arc-shaped clamping plates 29 from sliding off, one side of the sliding block 22 is fixedly connected with a first connecting rod 292, the first connecting rod 292 can drive the slide block 22 to move horizontally.

Further, the driving mechanism 3 includes a motor 31, a fixed block 32 is fixedly connected to an outer wall of the motor 31, one side of the fixed block 32 is fixedly connected to an inner wall of the connecting portion 12, the fixed block 32 can fix the motor 31, the first rotating rods 33 are symmetrically and rotatably connected to a surface of the connecting portion 12, a driving output end of the motor 31 is fixedly connected to one end of one set of the first rotating rods 33, by turning on the motor 31, a driving shaft of the motor 31 can drive one set of the first rotating rods 33 to rotate, one end of each set of the first rotating rods 33 is fixedly connected to a synchronizing wheel 34, a synchronous belt 35 is drivingly connected between the two sets of the synchronizing wheels 34, one set of the first rotating rods 33 drives the other set of the first rotating rods 33 to synchronously rotate in the same direction through the two sets of the synchronizing wheels 34 and the synchronous belt 35, a second connecting rod 36 is fixedly connected to an outer wall of the synchronous belt 35, and the synchronous belt 35 can drive the second connecting rod 36 to move, second guide slot 37 has been seted up to the outer wall symmetry of connecting portion 12, the equal sliding connection of inner wall of two sets of second guide slot 37 has second guide block 38, one side fixedly connected with U type sliding plate 39 of two sets of second guide block 38, U type sliding plate 39 can drive second guide block 38 and remove along the perpendicular direction in surface of second guide slot 37, contact slot 391 has been seted up to one side of U type sliding plate 39, the one end of second connecting rod 36 and the inner wall swing joint of contact slot 391, second connecting rod 36 can drive U type sliding plate 39 vertical direction through contact slot 391 and remove, one side fixedly connected with third connecting rod 392 of U type sliding plate 39, U type sliding plate 39 can drive third connecting rod 392 vertical direction and remove, the one end fixedly connected with half gear 393 of a set of first runner pole 33, first runner pole 33 can drive half gear 393 and rotate.

Further, the slitting mechanism 4 comprises a third guide block 41, one end of a third connecting rod 392 is fixedly connected with one side of the third guide block 41, the third connecting rod 392 can drive the third guide block 41 to move in the vertical direction, third guide grooves 42 are symmetrically formed in the inner wall of the connecting portion 12, the third guide block 41 is slidably connected with the third guide grooves 42, the third guide block 41 can move in the vertical direction along the surface of the third guide grooves 42, fourth connecting rods 43 are fixedly connected to the opposite sides of the two groups of third guide blocks 41, a slitting machine body 44 is fixedly connected between the two groups of fourth connecting rods 43, the third guide block 41 can drive the slitting machine body 44 to move in the vertical direction through the fourth connecting rods 43, slitting machine bodies 44 are opened, slitting of gyroscope rotation wheel blanks can be conveniently realized, fixing rods 45 are symmetrically and fixedly connected to the inner wall of the connecting portion 12, fixedly connected with arc blowing board 46 between two sets of dead levers 45, treat the gyroscope swiveling wheel stock of cutting and can place the surface at arc blowing board 46, improve the stability when cutting gyroscope swiveling wheel stock of cutting machine body 44, the outer wall of arc blowing board 46 and the last fixed surface of hopper 13 down are connected, gyroscope swiveling wheel stock after cutting can drop the inside of hopper 13 down, and drop to the inside of outside collection container through hopper 13 down, the inner wall fixed mounting of arc blowing board 46 has second slipmat 47, the stability of gyroscope swiveling wheel stock can be treated to cut by effectual improvement to second slipmat 47.

Further, feed mechanism 5 is including toothed plate 51, the one end of head rod 292 and one side fixed connection of toothed plate 51, toothed plate 51 can drive head rod 292 horizontal direction and remove, draw-in groove 52 has been seted up to the upper surface of processing platform 1, the inner wall sliding connection of draw-in groove 52 has fixture block 53, the lower surface of toothed plate 51 and the last fixed surface of fixture block 53 are connected, toothed plate 51 can drive fixture block 53 and remove along the horizontal surface direction of draw-in groove 52, the surface of connecting portion 12 rotates and is connected with second dwang 54, the one end fixedly connected with drive gear 55 of second dwang 54, drive gear 55 and toothed plate 51 meshing connection, pivoted drive gear 55 can drive toothed plate 51 horizontal direction and remove, drive gear 55 and half gear 393 meshing connection, pivoted half gear 393 can drive gear 55 intermittent type and rotate.

A stable use method of a gyroscope comprises the following steps:

firstly, clamping a blank of a gyroscope rotating wheel

Through the knob handle 28, the handle 28 drives the double-threaded screw 27 to rotate, the double-threaded screw 27 drives the two groups of first guide blocks 26 to move oppositely, the first guide blocks 26 drive the arc-shaped clamping plate 29 and the first anti-slip pads 291 to move in the vertical direction, and when the inner walls of the two groups of first anti-slip pads 291 contact with the outer wall of the tubular gyroscope rotating wheel blank and clamp the tubular gyroscope rotating wheel blank, the knob handle 28 is stopped, so that the clamping of the tubular gyroscope rotating wheel blank to be slit is conveniently completed, and the stability of the tubular gyroscope rotating wheel blank to be slit subsequently is effectively improved;

step two, automatic feeding of gyroscope rotating wheel blank

By starting the motor 31, the motor 31 drives one set of first rotating rods 33 to rotate, one set of first rotating rods 33 drives the other set of first rotating rods 33 to rotate through two sets of synchronous wheels 34 and synchronous belts 35, one set of first rotating rods 33 drives the half gear 393 to rotate, the half gear 393 drives the transmission gear 55 to rotate, the transmission gear 55 drives the toothed plate 51 to move, the toothed plate 51 drives the clamping block 53 to move and drives the sliding block 22 to move through the first connecting rod 292, the sliding block 22 drives the moving plate 21 to move, the moving plate 21 drives the tubular gyroscope to rotate the wheel blank to move, when the half gear 393 is not engaged with the transmission gear 55, the transmission gear 55 stops rotating, the toothed plate 51 stops moving, thereby conveniently completing the automatic feeding of the tubular gyroscope rotating wheel blank, the convenience of subsequently cutting the tubular gyroscope rotating wheel blank is effectively improved, and the efficiency of subsequently cutting the tubular gyroscope rotating wheel blank is effectively improved;

step three, cutting gyroscope rotating wheel blanks in batches

By starting the splitting machine body 44, the synchronous belt 35 drives the second connecting rod 36 to move downwards, the second connecting rod 36 drives the U-shaped sliding plate 39 to move downwards, the U-shaped sliding plate 39 drives a set of third guide blocks 41 to move downwards through the third connecting rod 392, the third guide blocks 41 drive the splitting machine body 44 to descend through the fourth connecting rod 43, when the cutting wheels of the descending splitting machine body 44 are in contact with the blanks of the gyro rotating wheel, the blanks of the gyro rotating wheel are cut off, so that one-time cutting of the blanks of the gyro rotating wheel is conveniently completed, because the synchronous belt 35 rotates ceaselessly, the synchronous belt 35 drives the U-shaped sliding plate 39 to reciprocate in the vertical direction through the second connecting rod 36, and then through the intermittent meshing of the half-side gear 393 and the transmission gear 55, the toothed plate 51 intermittently drives the blanks of the tubular gyro rotating wheel to intermittently advance, so that the splitting machine body 44 completes batch splitting of the blanks of the tubular gyro rotating wheel, and then the efficiency of cutting gyroscope swiveling wheel stock has effectually been improved.

The working principle is as follows: when the gyroscope rotating wheel blank needs to be cut, a worker firstly turns the knob handle 28, the handle 28 drives the double-threaded screw 27 to rotate, the double-threaded screw 27 drives the two groups of first guide blocks 26 to move back to back along the surface vertical direction of the first guide groove 25, the two groups of first guide blocks 26 drive the corresponding arc-shaped clamping plates 29 and the first anti-slip pads 291 to move in the vertical direction, at the moment, the two groups of arc-shaped clamping plates 29 and the two groups of first anti-slip pads 291 are separated, then one end of the tubular gyroscope rotating wheel blank to be cut is inserted into the central position between the two groups of first anti-slip pads 291, the other end of the tubular gyroscope rotating wheel blank is in surface contact with the second anti-slip pads 47, the other end of the tubular gyroscope rotating wheel blank vertically corresponds to the cutting wheel of the cutting machine body 44, at the moment, the handle 28 drives the double-threaded screw 27 to rotate through the reverse knob handle 28, and the double-threaded screw 27 drives the two groups of first guide blocks 26 to move oppositely along the surface vertical direction of the first guide groove 25 The two sets of first guide blocks 26 drive the corresponding arc-shaped clamping plates 29 and the corresponding first anti-slip pads 291 to move vertically until the inner walls of the two sets of first anti-slip pads 291 contact the outer wall of the tubular gyroscope rotating wheel blank and clamp the tubular gyroscope rotating wheel blank tightly, and then the knob handle 28 is stopped, so that the clamping of the tubular gyroscope rotating wheel blank to be cut is conveniently completed, the stability of the subsequent tubular gyroscope rotating wheel blank is effectively improved, subsequently, the motor 31 and the cutting machine body 44 are simultaneously started, the driving shaft of the motor 31 drives the corresponding set of first rotating rods 33 to rotate, one set of first rotating rods 33 drives the other set of first rotating rods 33 to synchronously rotate in the same direction through the two sets of synchronizing wheels 34 and the synchronizing belt 35, one set of first rotating rods 33 drives the half-side gear 393 to rotate, and the half-side gear 393 drives the transmission gear 55 to rotate at the same time, the transmission gear 55 rotates and drives the toothed plate 51 to move horizontally, the toothed plate 51 drives the fixture block 53 to move horizontally along the surface of the clamping groove 52 and drives the slide block 22 to move horizontally along the surface of the slide rail 23 through the first connecting rod 292, the slide block 22 drives the moving plate 21 to move synchronously, the moving plate 21 drives the tubular gyroscope rotating wheel blank clamped by the two sets of arc-shaped clamping plates 29 to move synchronously, at the moment, the tubular gyroscope rotating wheel blank slides on the surface of the second anti-skid pad 47, when the half gear 393 is not meshed with the transmission gear 55, the transmission gear 55 stops rotating, the toothed plate 51 stops moving, so that the automatic feeding of the tubular gyroscope rotating wheel blank is conveniently completed, the convenience of the subsequent tubular gyroscope rotating wheel blank is effectively improved, and the efficiency of the subsequent tubular gyroscope rotating wheel blank is effectively improved, meanwhile, the driving shaft of the motor 31 drives the corresponding set of first rotating rods 33 to rotate, one set of first rotating rods 33 drives the other set of first rotating rods 33 to synchronously rotate in the same direction through the two sets of synchronizing wheels 34 and the synchronous belt 35, the synchronous belt 35 drives the second connecting rod 36 to vertically move downwards, the second connecting rod 36 drives the U-shaped sliding plate 39 to vertically move downwards, the U-shaped sliding plate 39 drives the corresponding set of third guide blocks 41 to vertically move downwards through the third connecting rod 392, at this time, the two sets of third guide blocks 41 vertically descend along the surface of the corresponding third guide grooves 42 and drive the splitting machine body 44 to synchronously descend through the two sets of fourth connecting rods 43, when the splitting wheels of the vertically descending splitting machine body 44 contact with the gyro wheel blanks, the gyro wheel blanks are cut off, and the cut gyro wheel blanks fall into the lower hopper 13, thereby convenient completion once of gyroscope swiveling wheel stock cut, because the rotation that hold-in range 35 does not stop, hold-in range 35 drives the reciprocal vertical direction of U type sliding plate 39 through second connecting rod 36 and goes up and down, rethread half-gear 393 and drive gear 55's intermittent type nature meshing for pinion rack 51 intermittent type nature drives the advance of tubulose gyroscope swiveling wheel stock intermittent type nature, thereby make the batch that cutting machine body 44 accomplished tubulose gyroscope swiveling wheel stock cut, and then the effectual efficiency of cutting gyroscope swiveling wheel stock that has improved.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.