CN215364688U - Tooling plate automatic lifting mechanism with anti-falling function - Google Patents

Abstract

The utility model discloses an automatic lifting mechanism for a tooling plate with an anti-drop function, comprising: a telescopic assembly, wherein the telescopic assembly includes a first plate body, a second casing, a second motor, a third gear, a first concave The slot and the first rack, the second shell is provided with two, one side of the second shell is symmetrically welded with the two third plates, and the other is one of the second shell. The side is welded to one side of the fourth plate body. The utility model drives the first gear to rotate by starting the first motor, the first gear drives the second gear to rotate, the second gear drives the first threaded through hole above it to rotate, and the rotation of the first threaded through hole drives the first threaded rod to move upward. , the first threaded rod pushes the first housing upward to lift the tooling plate upwards, reducing the collision and instability during lifting, thereby reducing the risk of the tooling plate being offset and falling, and reducing the damage to the tooling plate.

Description

Tooling plate automatic lifting mechanism with anti-falling function

The technical field is as follows:

the utility model relates to the technical field of automatic lifting mechanisms of tooling plates, in particular to an automatic lifting mechanism of a tooling plate with an anti-falling function.

Background art:

with the development of science and technology, the demand for tooling plates is more and more, and the application is diversified;

the existing tooling plate lifting mechanism still has certain problems when in use:

the existing lifting mechanism consumes physical power of operators due to the fact that the lifting height is manually controlled, working time of production of the tooling plate is prolonged, and production efficiency of the tooling plate is reduced;

secondly, current hoist mechanism when the height of promotion frock board, easy bump and the unstable condition of production can lead to the frock board to have the skew risk of dropping to cause irrecoverable harm to the frock board, for this reason, provide a frock board automatic lifting mechanism with anti-drop function.

The utility model has the following contents:

the utility model aims to provide an automatic lifting mechanism of a tooling plate with an anti-falling function, so as to solve the problems in the background technology.

The utility model is implemented by the following technical scheme: the utility model provides a frock board automatic lifting mechanism with prevent falling function, includes:

the telescopic assembly comprises a first plate body, a second shell, a second motor, a third gear, a first groove and a first rack;

the clamping assembly comprises a third motor, a first through groove, a second plate body, a third plate body, a fourth gear, a fourth plate body, a second rack, a second groove, a first sliding groove and a first sliding block;

the second casing sets up two altogether, one the symmetrical welding of one side of second casing has two the third plate body, another one side of second casing weld in one side of fourth plate body, the opposite side of fourth plate body weld in one side of second plate body, first logical groove is seted up in the upper surface of second plate body.

As further preferable in the present technical solution: a lifting assembly is arranged below the telescopic assembly and comprises a first motor, a first gear, a second gear, a first threaded through hole, a first threaded rod and a first shell;

the outer side wall of the third motor is mounted on the inner side wall of the first through groove, the output shaft of the third motor is welded on the inner side wall of the fourth gear, the outer side wall of the fourth gear is meshed with the front surface of the second rack, the first sliding groove is formed in the front surface of the second groove, the number of the first sliding blocks is two, the two first sliding blocks are symmetrically welded on two sides of the fourth plate body, and the outer side wall of each first sliding block is slidably connected to the inner side wall of the first sliding groove;

the output shaft of first motor weld in the inside wall of first gear, the second gear sets up four altogether, four the lateral wall of second gear all meshes in the lateral wall of first gear, first screw thread through-hole sets up in the upper surface of second gear, the inside wall threaded connection of first screw thread through-hole in the lateral wall of first threaded rod, the one end of first threaded rod pass through the bearing rotate connect in the lower surface of first casing for promote first casing.

As further preferable in the present technical solution: the utility model discloses a portable electronic device, including first plate body, first gear, second gear, first plate body sets up two altogether two first recess has been seted up to the lateral wall symmetry of first plate body, first rack weld in the inside wall of first recess, the front surface of first rack mesh in the lateral wall of third gear, the inside wall of third gear weld in the output shaft of second motor, one side of third gear weld in the inside wall of second casing, the lateral wall of first plate body run through in the output shaft of second motor for the position of flexible first plate body is used for pressing from both sides tight frock board, improves the stability of frock board.

As further preferable in the present technical solution: two fifth plate bodies are symmetrically installed on the outer side wall of the first motor, a fixed block is welded on the lower surface of each fifth plate body, and a box body is welded on the lower surface of each fixed block and used for fixing the position of the first motor through the arrangement of the fifth plate bodies.

As further preferable in the present technical solution: the utility model discloses a portable electronic device, including first casing, second casing, first slider, second slider, first shell, second shell, first shell and second shell, the inside wall symmetrical welding of first casing has two sixth plate bodys, the second spout has been seted up to one side of sixth plate bodys, the inside wall sliding connection of second spout has the second slider, one side of second slider weld in the lateral wall of second casing, and then make things convenient for the second casing to slide.

As further preferable in the present technical solution: the second recess set up in the front surface of third plate body, the inside wall of third plate body weld in the inside wall of second recess, the lateral wall laminating of first plate body has the second to lead to the groove, the second leads to the groove and sets up the upper surface in first casing, the lower skin weld of first plate body has the circular plate body of second, the front surface weld of third plate body has the third slider, the lateral wall sliding connection of third slider leads to the groove in the inside wall of second spout, leads to the groove through setting up the second, makes things convenient for first plate body to slide.

As further preferable in the present technical solution: circular spout has been seted up to the lower surface of second gear, the inside wall sliding connection of circular spout has circular slider, circular slider's lower surface welding has circular body, the lower surface of circular body welds in the inboard diapire of box, through sliding circular slider in circular spout for supplementary rotation second gear.

As further preferable in the present technical solution: the first threaded rod is kept away from the one end welding of first casing has first circular plate body, the lateral wall threaded connection of first threaded rod has second screw thread through-hole, the upper surface at the box is seted up to second screw thread through-hole, through first circular plate body, prevents that first threaded rod from deviating from in the first screw thread through-hole.

The utility model has the advantages that:

1. according to the utility model, the fourth gear is driven to rotate on the second rack by starting the third motor, so that the fourth plate body and the third plate body are moved close to each other, the fourth plate body and the third plate body drive the two second shells to move close to each other, and the first plate body is driven to slide in the second through groove to clamp the tooling plate, so that the purpose of clamping and fixing the tooling plate is achieved, the physical strength consumed by operators is reduced through electric drive, the working time of production of the tooling plate is reduced, and the production efficiency of the tooling plate is improved.

2. According to the utility model, the first motor is started to drive the first gear to rotate, the first gear drives the second gear to rotate, the second gear drives the first threaded through hole above the second gear to rotate, the first threaded through hole rotates to drive the first threaded rod to move upwards, and the first threaded rod pushes the first shell to move upwards, so that the tooling plate is lifted upwards, and the conditions of collision and instability during lifting are reduced, thus the risk of offset and falling of the tooling plate is reduced, and the damage to the tooling plate is reduced.

Description of the 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 a schematic view of the structure of the area B in FIG. 1 according to the present invention;

fig. 3 is a schematic structural view of the telescopic assembly and a sixth plate body of the present invention;

FIG. 4 is a schematic view of the structure of area A of FIG. 1 according to the present invention;

fig. 5 is a schematic structural view of a clamping assembly and a sixth plate body according to the present invention;

in the figure: 1. a lifting assembly; 101. a first motor; 102. a first gear; 103. a second gear; 104. a first threaded through hole; 105. a first threaded rod; 106. a first housing; 2. a telescoping assembly; 201. a first plate body; 202. a second housing; 203. a second motor; 204. a third gear; 205. a first groove; 206. a first rack; 3. a clamping assembly; 301. a third motor; 302. a first through groove; 303. a second plate body; 304. a third plate body; 305. a fourth gear; 306. a fourth plate body; 307. a second rack; 308. a second groove; 309. a first chute; 310. a first slider; 4. a fifth plate body; 5. a fixed block; 6. a first circular plate body; 7. a circular tube body; 8. a circular slider; 9. a circular chute; 10. a second threaded through hole; 11. a second circular plate body; 12. a sixth plate body; 13. a second chute; 14. a second through groove; 15. a second slider; 16. a third slider; 17. and (4) a box body.

The specific implementation mode is as follows:

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.

In an embodiment, referring to fig. 1-5, the present invention provides a technical solution: the utility model provides a frock board automatic lifting mechanism with prevent falling function, includes:

the telescopic assembly 2 comprises a first plate 201, a second shell 202, a second motor 203, a third gear 204, a first groove 205 and a first rack 206;

the clamping assembly 3 comprises a third motor 301, a first through groove 302, a second plate 303, a third plate 304, a fourth gear 305, a fourth plate 306, a second rack 307, a second groove 308, a first sliding groove 309 and a first sliding block 310;

two second shells 202 are arranged, two third plate bodies 304 are symmetrically welded to one side of one second shell 202, one side of the other second shell 202 is welded to one side of a fourth plate body 306, the other side of the fourth plate body 306 is welded to one side of a second plate body 303, and a first through groove 302 is formed in the upper surface of the second plate body 303.

In this embodiment, specifically: a lifting assembly 1 is arranged below the telescopic assembly 2, and the lifting assembly 1 comprises a first motor 101, a first gear 102, a second gear 103, a first threaded through hole 104, a first threaded rod 105 and a first shell 106;

the outer side wall of the third motor 301 is installed on the inner side wall of the first through groove 302, the output shaft of the third motor 301 is welded on the inner side wall of the fourth gear 305, the outer side wall of the fourth gear 305 is meshed with the front surface of the second rack 307, the first sliding groove 309 is formed in the front surface of the second groove 308, two first sliding blocks 310 are arranged, the two first sliding blocks 310 are symmetrically welded on two sides of the fourth plate 306, and the outer side wall of the first sliding block 310 is slidably connected to the inner side wall of the first sliding groove 309;

the output shaft of first motor 101 welds in the inside wall of first gear 102, second gear 103 sets up four altogether, the lateral wall of four second gears 103 all meshes in the lateral wall of first gear 102, first screw through-hole 104 is seted up in the upper surface of second gear 103, the inside wall threaded connection of first screw through-hole 104 is in the lateral wall of first threaded rod 105, the one end of first threaded rod 105 is passed through the bearing and is rotated and connect in the lower surface of first casing 106, drive first gear 102 through starting first motor 101 and rotate, first gear 102 drives second gear 103 and rotates, drive first screw through-hole 104 through second gear 103 simultaneously and rotate, first screw through-hole 104 drives first threaded rod 105 upward movement, then promote first casing 106 upward movement.

In this embodiment, specifically: first plate body 201 sets up two altogether, two first recesses 205 have been seted up to two first plate body 201's lateral wall symmetry, first rack 206 welds in the inside wall of first recess 205, the front surface of first rack 206 meshes in the lateral wall of third gear 204, the inside wall of third gear 204 welds in the output shaft of second motor 203, one side of third gear 204 welds in the inside wall of second casing 202, the lateral wall of first plate body 201 runs through in the output shaft of second motor 203, drive third gear 204 through starting second motor 203 and rotate, third gear 204 drives first rack 206 upward movement, first rack 206 drives first plate body 201 upward movement, it is spacing to the frock board.

In this embodiment, specifically: two fifth plate bodies 4 are symmetrically installed on the outer side wall of the first motor 101, fixing blocks 5 are welded on the lower surfaces of the fifth plate bodies 4, and a box body 17 is welded on the lower surfaces of the fixing blocks 5 and used for fixing the position of the first motor 101 and preventing the first motor 101 from moving through arrangement of the fifth plate bodies 4.

In this embodiment, specifically: two sixth plate bodies 12 are symmetrically welded on the inner side wall of the first shell 106, a second chute 13 is formed in one side of the sixth plate body 12, a second sliding block 15 is connected to the inner side wall of the second chute 13 in a sliding mode, one side of the second sliding block 15 is welded on the outer side wall of the second shell 202, and the second sliding block 15 slides in the second chute 13 and is used for assisting in sliding the second shell 202 and improving the stability of the second shell 202.

In this embodiment, specifically: the front surface of third plate body 304 is seted up in second recess 308, the inside wall of third plate body 304 welds in the inside wall of second recess 308, the laminating of the lateral wall of first plate body 201 has the logical groove 14 of second, the logical groove 14 of second is seted up in the upper surface of first casing 106, the lower surface welding of first plate body 201 has the circular plate body 11 of second, the front surface welding of third plate body 304 has third slider 16, the lateral wall sliding connection of third slider 16 is in the inside wall of second spout 13, slide in second spout 13 through third slider 16, when being used for supplementary slip third plate body 304, can fix third plate body 304 again, wherein set up the logical groove 14 of second, it slides in logical groove 14 to be used for first plate body 201.

In this embodiment, specifically: circular spout 9 has been seted up to second gear 103's lower surface, circular spout 9's inside wall sliding connection has circular slider 8, circular slider 8's lower surface welding has circular body 7, the lower surface of circular body 7 welds in the inboard diapire of box 17, inside wall sliding connection through circular spout 9 has circular slider 8, when being used for supplementary rotatory second gear 103, be used for fixed second gear 103 again, wherein circular slider 8's lower surface welding is on circular body 7, a position for fixed second gear 103.

In this embodiment, specifically: the first round plate body 6 is welded at one end, far away from the first shell 106, of the first threaded rod 105, the second threaded through hole 10 is connected to the outer side wall of the first threaded rod 105 in a threaded mode, the second threaded through hole 10 is formed in the upper surface of the box body 17, the second threaded through hole 10 and the first round plate body 6 are arranged, the second threaded through hole 10 is used for fixing the first threaded rod 105, the first threaded rod 105 is prevented from inclining, and the first threaded rod 105 is prevented from being separated from the first threaded through hole 104 due to the arrangement of the first round plate body 6.

In this embodiment: a switch group for controlling the start and the stop of the first motor 101, the second motor 203 and the third motor 301 is installed on one side of the box 17, and the switch group is connected with an external commercial power to supply power to the first motor 101, the second motor 203 and the third motor 301.

In this embodiment: the first motor 101 is model number DS-12SSN 20; the second motor 203 and the third motor 301 are of the type GA 37-520.

Working principle or structural principle: when the tool is used, a tool plate is placed on the first shell 106, the second motor 203 is started to drive the third gear 204 to rotate, the third gear 204 drives the first rack 206 to move upwards, the first rack 206 drives the first plate body 201 to move upwards to limit the tool plate, then the third motor 301 is started to rotate, then the output shaft of the third motor 301 drives the fourth gear 305 to rotate on the second rack 307, so that the fourth plate body 306 and the third plate body 304 are driven to move close to each other, the fourth plate body 306 and the third plate body 304 drive the two second shell bodies 202 to move close to each other, so that the first plate body 201 is driven to slide in the second through groove 14 to clamp the tool plate, then the first motor 101 is started to drive the first gear 102 to rotate, the first gear 102 drives the second gear 103 to rotate and simultaneously drives the first thread through hole 104 on the second gear 103 to rotate, the first thread through hole 104 drives the first threaded rod 105 to move upwards, the first housing 106 is then pushed upward, lifting the tooling plate upward.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (8)

1. A tooling plate automatic lifting mechanism with anti-dropping function is characterized in that, comprising: A telescopic assembly (2), the telescopic assembly (2) includes a first plate body (201), a second housing (202), a second motor (203), a third gear (204), and a first groove (205) ) and the first rack (206); A clamping assembly (3), the clamping assembly (3) comprising a third motor (301), a first through groove (302), a second plate body (303), a third plate body (304), and a fourth gear (305), a fourth plate body (306), a second rack (307), a second groove (308), a first chute (309) and a first slider (310); There are two second shells (202) in total, one of the second shells (202) is symmetrically welded with two third plates (304) on one side, and the other is the second shell One side of (202) is welded to one side of the fourth plate body (306), and the other side of the fourth plate body (306) is welded to one side of the second plate body (303), so The first through groove (302) is opened on the upper surface of the second plate body (303). 2. The automatic lifting mechanism for a tooling plate with an anti-drop function according to claim 1, wherein a lifting assembly (1) is installed below the telescopic assembly (2), and the lifting assembly (1) comprises a first motor (101), a first gear (102), a second gear (103), a first threaded through hole (104), a first threaded rod (105) and a first housing (106); The outer side wall of the third motor (301) is mounted on the inner side wall of the first through slot (302), and the output shaft of the third motor (301) is welded to the inner side wall of the fourth gear (305). , the outer side wall of the fourth gear (305) is engaged with the front surface of the second rack (307), and the first chute (309) is opened on the front surface of the second groove (308) , there are two first sliders (310) in total, and the two first sliders (310) are symmetrically welded to both sides of the fourth plate body (306), and the first sliders (310) ) is slidably connected to the inner sidewall of the first chute (309); The output shaft of the first motor (101) is welded to the inner side wall of the first gear (102), and a total of four second gears (103) are arranged on the outer side of the four second gears (103). The walls are all engaged with the outer side wall of the first gear (102), the first threaded through holes (104) are opened on the upper surface of the second gear (103), and the first threaded through holes (104) The inner sidewall of the first threaded rod (105) is threadedly connected to the outer sidewall of the first threaded rod (105), and one end of the first threaded rod (105) is rotatably connected to the lower surface of the first housing (106) through a bearing. 3. The automatic lifting mechanism for a tooling plate with an anti-drop function according to claim 1, characterized in that: a total of two first plate bodies (201) are provided, and two of the first plate bodies (201) are provided. Two first grooves (205) are symmetrically opened on the outer sidewall of the first rack (206), the first rack (206) is welded to the inner sidewall of the first groove (205), and the first rack (206) is The front surface is engaged with the outer side wall of the third gear (204), and the inner side wall of the third gear (204) is welded to the output shaft of the second motor (203). One side is welded to the inner side wall of the second casing (202), and the outer side wall of the first plate body (201) penetrates the output shaft of the second motor (203). 4. The automatic lifting mechanism for a tooling plate with an anti-dropping function according to claim 2, wherein two fifth plate bodies (4) are symmetrically installed on the outer side wall of the first motor (101), so that the A fixing block (5) is welded on the lower surface of the fifth plate body (4), and a box body (17) is welded on the lower surface of the fixing block (5). 5. The tooling plate automatic lifting mechanism with anti-drop function according to claim 2, characterized in that: two sixth plate bodies (12) are symmetrically welded to the inner side wall of the first shell (106), One side of the sixth plate body (12) is provided with a second sliding groove (13), and the inner side wall of the second sliding groove (13) is slidably connected with a second sliding block (15), and the second sliding groove (13) is slidably connected with a second sliding block (15). One side of the block (15) is welded to the outer side wall of the second casing (202). 6. The automatic lifting mechanism for a tooling plate with an anti-dropping function according to claim 1, wherein the second groove (308) is opened on the front surface of the third plate body (304), so that the The inner side wall of the third plate body (304) is welded to the inner side wall of the second groove (308), and the outer side wall of the first plate body (201) is fitted with the second through groove (14), so The second through groove (14) is opened on the upper surface of the first shell (106), the lower surface of the first plate body (201) is welded with a second circular plate body (11), and the third plate A third sliding block (16) is welded on the front surface of the body (304), and the outer side wall of the third sliding block (16) is slidably connected to the inner side wall of the second chute (13). 7. The automatic lifting mechanism of the tooling plate with anti-dropping function according to claim 2, wherein a circular chute (9) is provided on the lower surface of the second gear (103), and the circular A circular sliding block (8) is slidably connected to the inner side wall of the chute (9), and a circular pipe body (7) is welded on the lower surface of the circular sliding block (8). The circular pipe body (7) The lower surface of the box is welded to the inner bottom wall of the box body (17). 8 . The automatic lifting mechanism for a tooling plate with an anti-dropping function according to claim 2 , wherein the first threaded rod ( 105 ) is away from the first housing ( 106 ). 9 .

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