CN214350759U - Device of screw is twisted to high efficiency - Google Patents

Abstract

The utility model discloses a device of screw is twisted to high efficiency, including telescopic hood, base and the pneumatic telescopic link of second, still including the translation mechanism that is used for improving work efficiency, weakens the damper of impact force and the automatically supported clamping structure, the both sides on base top all are connected with the support column, and the top of support column installs the roof, the workstation is evenly installed on the top of base. The utility model discloses a first pneumatic telescopic link extension makes telescopic cover press and fixes a position on the work piece, extend through the work of the pneumatic telescopic link of second and make the both sides centre gripping of clamp splice to the screw body, the rotatory decline in-process of revolving knife, extrusion deformation in the expanding spring, fixed cover removes to the telescopic cover inboard, and the rotatory in-process of screw body, the movable block removes simultaneously in the spout, make the clamp splice rotate along with the screw body, the screw body stabilizes the back, the work of the pneumatic telescopic link of second shortens and makes the clamp splice keep away from the screw body, make the screw body in the smooth manhole, realize the automatic screw body of holding.

Description

Device of screw is twisted to high efficiency

Technical Field

The utility model relates to a twist screw technical field specifically is a device of screw is twisted to high efficiency.

Background

Along with the development of economy, the automated machine replaces ancient manual processing gradually, automated processing is not only work efficiency high, and the precision is high, twist screw body work to the work piece and generally carry out work through handheld screw body sword of staff, work efficiency is extremely low, and easily make the staff be injured, fall out in order to avoid the screw body follow hole, generally process through handheld screw body, danger is high, but there are a lot of deficiencies in the same of present last screw body device, do not have multistation simultaneous processing, thereby can not realize the high efficiency.

With the continuous installation and use of the device for screwing the screw body, the following problems are found in the use process:

1. the existing screw screwing devices do not work simultaneously in multiple stations in the daily use process, so that the working efficiency is low.

2. And the device for screwing the screw does not have a structure for automatically supporting the screw body in the using process, and the screw body is easy to fall out of the hole.

3. And the device of twisting the screw does not have the structure of carrying out the shock attenuation to the workstation in the use, avoids the impact force to make the damage of device.

Therefore, it is necessary to design a device for screwing screws with high efficiency.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a device of screw is twisted to high efficiency to it does not have high efficiency, automatic screw body and the absorbing problem of supporting to provide a device of current screw is twisted to high efficiency in solving above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a device for efficiently screwing screws comprises a telescopic cover, a base, a second pneumatic telescopic rod, a translation mechanism for improving the working efficiency, a damping mechanism for weakening the impact force and an automatic supporting clamping structure;

the two sides of the top end of the base are both connected with supporting columns, a top plate is mounted at the top ends of the supporting columns, illuminating lamps are mounted on the outer wall of one side of each supporting column, a controller is mounted on the outer wall of the other side of each supporting column, and the translation mechanism is mounted on the inner wall of the base;

the top end of the base is uniformly provided with a workbench, the inner sides of the workbenches are provided with object placing tables, a workpiece is arranged above the object placing tables, a screw body is arranged above the workpiece, and the damping mechanism is arranged on the inner wall of the workbench;

first pneumatic telescopic link is installed to the one end outer wall of roof, and the below of first pneumatic telescopic link installs driving motor, driving motor's output is installed rotatory sword through the drive shaft, clamping structure installs in the outside of rotatory sword.

Preferably, a positive and negative motor is installed to the inner wall of roof, and the output of a positive and negative motor has the lead screw through drive shaft connection, the slider is installed to the outer wall of lead screw, the one end of slider is connected in the outer wall of a pneumatic telescopic link.

Preferably, the clamping structure comprises a fixed cover, the fixed cover is arranged on the outer side of the rotary knife, a telescopic cover is arranged below the fixed cover, telescopic springs are uniformly arranged on the inner wall of the telescopic cover, and the top ends of the telescopic springs are connected with the bottom end of the fixed cover.

Preferably, the inner walls of the two sides of the telescopic cover are provided with second pneumatic telescopic rods, one ends of the second pneumatic telescopic rods are connected with connecting plates, and the inner walls of the connecting plates are provided with clamping blocks.

Preferably, the translation mechanism includes positive and negative motor of second, gear and rack, the positive and negative motor of second is installed in the inner wall of base, the output of the positive and negative motor of second has the gear through drive shaft connection, the rack is installed to the bottom of gear top workstation.

Preferably, damper includes horizontal pole, bracing piece, damping spring and the lantern ring, the horizontal pole is installed in the inner wall of workstation, damping spring is all installed to the both sides outer wall of horizontal pole, and damping spring's one end all is connected with the lantern ring, the equal activity hinge in top of the lantern ring has the bracing piece, and the top activity hinge of bracing piece puts the bottom of thing platform.

Preferably, the outer wall of the connecting plate is provided with a sliding groove, and one side of the clamping block is connected with the sliding groove through a moving block.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) the rotary knife, the damping springs, the supporting rods and the object placing table are mounted, the object placing table moves downwards through the rotary impact force of the rotary knife, the included angle between the supporting rods is enlarged through pressure, the damping springs are extruded and deformed, the effect of damping and buffering the impact force is achieved, and the device is prevented from being damaged by the impact force;

(2) the second positive and negative motor drives the gear to rotate, the gear is meshed with the rack, the rack drives the workbench to move to one end and move to the position below the rotary knife to be machined, after machining is finished, the workbench moves to an original position and takes down the machined workpiece, meanwhile, the workbench on two sides simultaneously drives the workpiece to move to a horizontal position below the rotary knife, the screw rod rotates through the work of the first positive and negative motor, the screw threads are matched, the slider drives the rotary knife to move left and right, and therefore the workpieces on two side stations are machined, and the working efficiency is improved through multi-directional simultaneous operation;

(3) the utility model discloses a screw body, including the first pneumatic telescopic link, the second pneumatic telescopic link, the spout, the clamp splice, rotatory sword, the movable block, fixed cover, expanding spring, the screw body, work piece and telescopic cover, it fixes a position to make the telescopic cover press on the work piece through the extension of first pneumatic telescopic link, make the both sides centre gripping of clamp splice to the screw body through the extension of second pneumatic telescopic link work, rotatory decline in-process of rotatory sword, extrusion deformation in the expanding spring, fixed cover removes to the telescopic cover inboard, and the rotatory in-process of screw body, the movable block removes simultaneously in the spout, make the clamp splice rotate along with the screw body, the screw body is stabilized the back, the work of second pneumatic telescopic link shortens and makes the clamp splice keep away from the screw body, make the screw body in the manhole smoothly, realize holding the screw body automatically.

Drawings

FIG. 1 is a schematic cross-sectional view of the device of the present invention;

FIG. 2 is a schematic view of the front view structure of the device of the present invention;

FIG. 3 is a schematic structural view of the translation mechanism of the present invention;

FIG. 4 is a schematic view of the structure of the damping mechanism of the present invention;

fig. 5 is an enlarged schematic view of a portion a of fig. 1 according to the present invention.

In the figure: 1. a support pillar; 2. an illuminating lamp; 3. a top plate; 4. a drive motor; 5. a first pneumatic telescopic rod; 6. a slider; 7. a rotary knife; 8. a screw rod; 9. a first positive and negative motor; 10. a controller; 11. a work table; 12. a tension spring; 13. a workpiece; 14. a base; 15. a telescopic cover; 16. a fixed cover; 17. a translation mechanism; 1701. a second positive and negative motor; 1702. a gear; 1703. a rack; 18. a placing table; 19. a damping mechanism; 1901. a cross bar; 1902. a support bar; 1903. a damping spring; 1904. a collar; 20. a screw body; 21. a second pneumatic telescopic rod; 22. a chute; 23. a moving block; 24. a clamping block; 25. a connecting plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1: referring to fig. 1-5, a device for screwing screws efficiently includes a telescopic cover 15, a base 14, a second pneumatic telescopic rod 21, a translation mechanism 17 for improving working efficiency, a damping mechanism 19 for damping impact force, and a clamping structure for automatic support;

the two sides of the top end of the base 14 are both connected with supporting columns 1, the top end of each supporting column 1 is provided with a top plate 3, the outer wall of one side of each supporting column 1 is provided with an illuminating lamp 2, the outer wall of the other side of each supporting column 1 is provided with a controller 10, the type of the controller 10 can be JY-PH160, and the translation mechanism 17 is arranged on the inner wall of the base 14;

the top end of the base 14 is uniformly provided with the workbench 11, the inner sides of the workbench 11 are provided with the object placing tables 18, the workpiece 13 is arranged above the object placing tables 18, the screw body 20 is arranged above the workpiece 13, and the damping mechanism 19 is arranged on the inner wall of the workbench 11;

a first pneumatic telescopic rod 5 is installed on the outer wall of one end of the top plate 3, the type of the first pneumatic telescopic rod 5 can be YQL890, a driving motor 4 is installed below the first pneumatic telescopic rod 5, the type of the driving motor 4 can be YE2-3KW-4, a rotary knife 7 is installed at the output end of the driving motor 4 through a driving shaft, and a clamping structure is installed on the outer side of the rotary knife 7;

referring to fig. 1-5, the device for efficiently screwing the screw further comprises a clamping structure, the clamping structure comprises a fixed cover 16, the fixed cover 16 is mounted on the outer side of the rotary knife 7, a telescopic cover 15 is mounted below the fixed cover 16, telescopic springs 12 are uniformly mounted on the inner wall of the telescopic cover 15, and the top ends of the telescopic springs 12 are connected with the bottom end of the fixed cover 16;

the inner walls of two sides of the telescopic cover 15 are respectively provided with a second pneumatic telescopic rod 21, the type of the second pneumatic telescopic rod 21 can be HD20180111, one end of the second pneumatic telescopic rod 21 is connected with a connecting plate 25, and the inner wall of the connecting plate 25 is provided with a clamping block 24;

the outer wall of the connecting plate 25 is provided with a sliding groove 22, and one side of the clamping block 24 is connected with the sliding groove 22 through a moving block 23;

specifically, as shown in fig. 1, 2 and 5, when the structure is used, the first pneumatic telescopic rod 5 extends to press the telescopic cover 15 against the workpiece 13 for positioning, the clamping blocks 24 clamp two sides of the screw body 20 through the working extension of the second pneumatic telescopic rod 21, the rotary knife 7 rotates and descends, the telescopic spring 12 extrudes and deforms, the fixed cover 16 moves towards the inner side of the telescopic cover 15, in the rotating process of the screw body 20, the moving block 23 moves in the sliding groove 22 simultaneously, the clamping blocks 24 rotate along with the screw body 20, and after the screw body 20 is stabilized, the second pneumatic telescopic rod 21 works and shortens to enable the clamping blocks 24 to be far away from the screw body 20, so that the screw body 20 smoothly enters the hole.

Example 2: the translation mechanism 17 comprises a second positive and negative motor 1701, a gear 1702 and a rack 1703, the second positive and negative motor 1701 is installed on the inner wall of the base 14, the type of the second positive and negative motor 1701 can be F-3420-1, the output end of the second positive and negative motor 1701 is connected with the gear 1702 through a driving shaft, and the rack 1703 is installed at the bottom end of the workbench 11 above the gear 1702;

a first positive and negative motor 9 is installed on the inner wall of the top plate 3, the type of the first positive and negative motor 9 can be 50KTYZ, the output end of the first positive and negative motor 9 is connected with a lead screw 8 through a driving shaft, a sliding block 6 is installed on the outer wall of the lead screw 8, and one end of the sliding block 6 is connected to the outer wall of the first pneumatic telescopic rod 5;

specifically, as shown in fig. 1 and 3, when the structure is used, the gear 1702 is driven to rotate by the second positive and negative motor 1701, the gear 1702 is meshed with the rack 1703, the rack 1703 drives the workbench 11 to move towards one end and move to the position below the rotary knife 7 for processing, after the processing is completed, the workbench 11 moves towards the original position, the processed workpiece 13 is taken down, meanwhile, the workbench 11 on the two sides simultaneously drives the workpiece 13 to move towards the horizontal position below the rotary knife 7, the screw rod 8 rotates through the work of the first positive and negative motor 9, the screw threads are matched, the slider 6 drives the rotary knife 7 to move left and right, so that the workpiece 13 on the stations on the two sides is processed, and the working efficiency is improved through multi-directional simultaneous operation.

Example 3: the damping mechanism 19 comprises a cross rod 1901, a support rod 1902, a damping spring 1903 and a lantern ring 1904, the cross rod 1901 is mounted on the inner wall of the workbench 11, the damping spring 1903 is mounted on the outer walls of the two sides of the cross rod 1901, one end of the damping spring 1903 is connected with the lantern ring 1904, the top end of the lantern ring 1904 is movably hinged with the support rod 1902, and the top end of the support rod 1902 is movably hinged with the bottom end of the object placing table 18;

specifically, as shown in fig. 4, when this structure is used, the object placing table 18 is moved downward by the rotational impact of the rotary knife 7, the included angle between the support rods 1902 is increased by the pressure, and the damping spring 1903 is deformed by being pressed, thereby achieving the effect of damping and buffering the impact force and preventing the device from being damaged by the impact force.

The output end of the controller 10 is electrically connected with the input ends of the illuminating lamp 2, the driving motor 4, the first pneumatic telescopic rod 5, the first forward and backward motor 9, the second forward and backward motor 1701 and the second pneumatic telescopic rod 21 through wires.

The working principle is as follows: when the device is used, firstly, a workpiece 13 is placed on a placing table 18 on the inner side of a workbench 11, a gear 1702 is driven to rotate through a second positive and negative motor 1701, the gear 1702 is meshed with a rack 1703, the rack 1703 drives the workbench 11 to move towards one end and move to the position below a rotary knife 7, then a telescopic cover 15 is pressed on the workpiece 13 to be positioned through extension of a first pneumatic telescopic rod 5, and clamping blocks 24 clamp two sides of a screw body 20 through working extension of a second pneumatic telescopic rod 21;

then, the driving motor 4 works to enable the rotary knife 7 to rotate, the first pneumatic telescopic rod 5 enables the rotary knife 7 to continuously descend, the screw body 20 is installed in a rotating hole, in the rotating process of the screw body 20, the moving block 23 moves in the sliding groove 22 simultaneously, the clamping block 24 rotates along with the screw body 20, after the screw body 20 is stabilized, the second pneumatic telescopic rod 21 works and shortens to enable the clamping block 24 to be far away from the screw body 20, the screw body 20 smoothly enters the hole, the object placing table 18 moves downwards through the rotating impact force of the rotary knife 7, the included angle between the supporting rods 1902 is increased through pressure, the damping spring 1903 is extruded and deformed, the effect of damping and buffering the impact force is achieved, and the device is prevented from being damaged by the impact force;

finally, the workbench 11 moves to the original position, the machined workpiece 13 is taken down, meanwhile, the workbench 11 on the two sides simultaneously drives the workpiece 13 to move to the horizontal position below the rotary cutter 7, the screw rod 8 rotates through the work of the first positive and negative motor 9, the slide block 6 drives the rotary cutter 7 to move left and right through threaded fit, and therefore the workpiece 13 on the stations on the two sides is machined, and the working efficiency is improved through multi-directional simultaneous operation.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a device of screw is twisted to high efficiency, includes telescopic cover (15), base (14) and second pneumatic telescopic link (21), its characterized in that: the device also comprises a translation mechanism (17) for improving the working efficiency, a damping mechanism (19) for weakening the impact force and a clamping structure for automatic support;

the two sides of the top end of the base (14) are connected with supporting columns (1), a top plate (3) is mounted at the top ends of the supporting columns (1), illuminating lamps (2) are mounted on the outer wall of one side of each supporting column (1), a controller (10) is mounted on the outer wall of the other side of each supporting column (1), and the translation mechanism (17) is mounted on the inner wall of the base (14);

the top end of the base (14) is uniformly provided with a workbench (11), the inner sides of the workbenches (11) are respectively provided with an object placing table (18), a workpiece (13) is arranged above the object placing table (18), a screw body (20) is arranged above the workpiece (13), and the damping mechanism (19) is arranged on the inner wall of the workbench (11);

first pneumatic telescopic link (5) are installed to the one end outer wall of roof (3), and driving motor (4) are installed to the below of first pneumatic telescopic link (5), rotatory sword (7) are installed through the drive shaft to the output of driving motor (4), clamping structure installs in the outside of rotatory sword (7).

2. A device for screwing a screw according to claim 1, wherein: first positive and negative motor (9) are installed to the inner wall of roof (3), and the output of first positive and negative motor (9) has lead screw (8) through drive shaft connection, slider (6) are installed to the outer wall of lead screw (8), the one end of slider (6) is connected in the outer wall of first pneumatic telescopic link (5).

3. A device for screwing a screw according to claim 1, wherein: the clamping structure comprises a fixed cover (16), the fixed cover (16) is installed on the outer side of the rotary knife (7), an expansion cover (15) is installed below the fixed cover (16), expansion springs (12) are evenly installed on the inner wall of the expansion cover (15), and the top ends of the expansion springs (12) are connected with the bottom end of the fixed cover (16).

4. A device for screwing a screw according to claim 3, wherein: second pneumatic telescopic link (21) are all installed to the both sides inner wall of flexible cover (15), and the one end of second pneumatic telescopic link (21) all is connected with connecting plate (25), clamp splice (24) are installed to the inner wall of connecting plate (25).

5. A device for screwing a screw according to claim 1, wherein: the translation mechanism (17) comprises a second positive and negative motor (1701), a gear (1702) and a rack (1703), the second positive and negative motor (1701) is installed on the inner wall of the base (14), the output end of the second positive and negative motor (1701) is connected with the gear (1702) through a driving shaft, and the rack (1703) is installed at the bottom end of the workbench (11) above the gear (1702).

6. A device for screwing a screw according to claim 1, wherein: damper (19) include horizontal pole (1901), bracing piece (1902), damping spring (1903) and lantern ring (1904), install in the inner wall of workstation (11) horizontal pole (1901), damping spring (1903) are all installed to the both sides outer wall of horizontal pole (1901), and damping spring (1903)'s one end all is connected with lantern ring (1904), the top of lantern ring (1904) all activity hinge has bracing piece (1902), and the top activity hinge of bracing piece (1902) puts the bottom of thing platform (18).

7. A device for screwing high efficiency screw according to claim 4, characterized in that: the outer wall of the connecting plate (25) is provided with a sliding groove (22), and one side of the clamping block (24) is connected with the sliding groove (22) through a moving block (23).

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