CN111745024A

CN111745024A - Mechanical automation system spiral-lock is put

Info

Publication number: CN111745024A
Application number: CN202010640767.6A
Authority: CN
Inventors: 李立红
Original assignee: Jiangsu University of Science and Technology
Current assignee: Jiangsu University of Science and Technology
Priority date: 2020-07-06
Filing date: 2020-07-06
Publication date: 2020-10-09

Abstract

The invention discloses a mechanical automatic buckle making device which comprises a bottom plate, a support column, a support, a vibrating motor, a charging barrel, a conveyor belt, a left support, a right support, a top plate, a movable plate, a lower die, a first cylinder and an upper die, wherein the lower die is arranged at the right lower part of the right end of the conveyor belt; a connecting plate is fixed between the left pillar and the right pillar, a lower guide rail is fixed at the top of the connecting plate, at least two lower guide wheels are arranged in the lower guide rail in a sliding manner, a lower mounting seat is installed at the top of each guide wheel, a lifting device is fixed at the top of each lower mounting seat, an upper mounting seat is fixed at the top of each lifting device, an upper guide rail is fixed at the bottom of each movable plate, an upper guide wheel connected with the upper guide rail in a sliding manner is fixed at the top of each upper mounting seat, and a material receiving disc is fixed on the outer wall of the right pillar; and a second cylinder is fixed on the inner wall of the left support, and an output shaft of the second cylinder is connected with the lifting device. The beneficial effects are as follows: convenient to use, degree of automation is high.

Description

Mechanical automation system spiral-lock is put

Technical Field

The invention relates to a mechanical automatic button making device.

Background

In the production process of the button, a material belt or a whole sheet of plate is usually cut or punched to form a blank, if a fastener is to be manufactured, a button blank is placed on a lower die, and then the upper die presses the button blank into a three-dimensional shape.

After the existing button making device presses the button blank, the button needs to be taken out of the lower die manually, and the mode is low in automation degree and inconvenient to use.

Disclosure of Invention

The invention aims to provide a mechanical automatic button making device which is convenient to use and high in automation degree.

In order to solve the technical problems, the invention adopts the technical scheme that:

a mechanical automatic buckle making device comprises a bottom plate, wherein a support column and a support are sequentially fixed on the top of the bottom plate from left to right, a vibration motor is fixed on the outer wall of the support column close to the top, a material cylinder is fixed on an output shaft of the vibration motor, a conveying belt is installed on the support, and a bottom outlet of the material cylinder is located above the left end of the conveying belt; a connecting plate is fixed between the left pillar and the right pillar, a lower guide rail is fixed at the top of the connecting plate, at least two lower guide wheels are arranged in the lower guide rail in a sliding manner, a lower mounting seat is mounted at the top of each guide wheel, a lifting device is fixed at the top of each lower mounting seat, an upper mounting seat is fixed at the top of each lifting device, an upper guide rail is fixed at the bottom of each movable plate, an upper guide wheel which is in sliding connection with the upper guide rail is fixed at the top of each upper mounting seat, and a material receiving disc is fixed on the outer wall of the right pillar; and a second cylinder is fixed on the inner wall of the left support, and an output shaft of the second cylinder is connected with the lifting device.

Preferably, in the above mechanical automatic buckle making device, a reinforcing plate connected to the bottom of the take-up pan is fixed to an outer wall of the right pillar.

Preferably, foretell mechanical automation system knot device, wherein elevating gear is including fixing the hollow tube at mount pad top down, fix go up the movable rod of mount pad bottom, it has last plectane and lower plectane to slide in the inner chamber of hollow tube, it is fixed with the rack board down to go up between plectane and the plectane, the outer wall of hollow tube is fixed with the motor cabinet, servo motor is installed at the top of motor cabinet, be fixed with on servo motor's the output shaft and extend to the rotation axis in the hollow tube inner chamber, the rotation axis is located be fixed with on the end in the hollow tube with the gear of rack board meshing, the bottom of movable rod extends to in the inner chamber of hollow tube and with it connects to go up the plectane.

Preferably, in the above mechanical automatic buckle making device, an end cap is fixed on the top of the hollow tube, and the movable rod passes through the end cap and is connected with the end cap in a sliding manner.

Preferably, in the above mechanical automatic buckle making device, a rotating shaft extending out of the hollow tube and rotatably connected to the hollow tube is fixed to an end of the gear away from the rotating shaft.

Preferably, the mechanical automatic buckle making device is provided with two lower guide wheels.

Preferably, in the above mechanical automatic button-making device, the output shaft of the second cylinder is connected to the outer wall of the hollow tube.

Preferably, the above mechanical automated buckle making device, wherein the rack plate is disposed in a vertical direction.

Preferably, in the above mechanical automatic buckle making device, the upper circular plate and the lower circular plate are adapted to the inner cavity of the hollow tube.

The technical effects of the invention are mainly reflected in that:

the lifting device can adjust the height, and the second cylinder can drive the lifting device to move left and right; when elevating gear height-adjusting, when second cylinder drive elevating gear moved left, the fly leaf can overturn, and the button on the lower mould can fall into the take-up (stock) pan, and design degree of automation is high like this, and it is convenient to use.

Drawings

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

FIG. 2 is a schematic structural view of the movable plate of FIG. 1 after being turned over;

FIG. 3 is a schematic structural diagram of the lifting device in FIG. 1;

FIG. 4 is an enlarged view of a portion A of FIG. 1;

fig. 5 is a partially enlarged view of fig. 2 at B.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly and clearly understood, the technical solutions in the embodiments of the present invention will be described below in detail and completely with reference to the accompanying drawings and the embodiments of the present invention. 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.

As shown in fig. 1, 2, 3, 4, and 5, a mechanical automation button making device includes a bottom plate 11, a support column 12 and a support 13 are sequentially welded on the top of the bottom plate 11 from left to right, a vibration motor 14 is fixed on the outer wall of the support column 12 close to the top through screws, a charging barrel 15 is fixed on the output shaft of the vibration motor 14, a conveyor belt 16 is installed on the support 13, and the outlet at the bottom of the charging barrel 15 is located above the left end of the conveyor belt 16.

The top of the bottom plate 11 is located on the right side of the support 13 and welded with the left pillar 21 and the right pillar 22, the tops of the left pillar 21 and the right pillar 22 are respectively welded with a top plate 23, the top of the top plate 23 is provided with a movable plate 24, the top plate 23 on the right side is movably connected with the movable plate 24 through hinges, a lower die 25 is fixed above the movable plate 24, an upper die 27 is connected above the lower die 25 through a first cylinder 26, and the lower die 25 is arranged on the right lower side of the right end of the conveyor belt 16.

The connecting plate 31 is welded between the left pillar 21 and the right pillar 22, a lower guide rail 41 is fixed at the top of the connecting plate 31 through screws, two lower guide wheels 42 are arranged in the lower guide rail 41 in a sliding mode, a lower mounting seat 43 is installed at the top of each guide wheel 42, a lifting device 5 is fixed at the top of each lower mounting seat 43, an upper mounting seat 6 is fixed at the top of each lifting device 5, an upper guide rail 61 is fixed at the bottom of the movable plate 24, and an upper guide wheel 62 connected with the upper guide rail 61 in a sliding mode is fixed at the top of the upper mounting seat 6.

A material receiving disc 71 is welded on the outer wall of the right strut 22; a second cylinder 75 is welded on the inner wall of the left support column 21, and the output shaft of the second cylinder 75 is connected with the lifting device 5.

The outer wall of the right pillar 22 in the invention is welded with a reinforcing plate 72 connected with the bottom of the receiving tray 71, so that the structure of the invention is more firm.

The technical effects of the invention are mainly reflected in that:

the lifting device 5 can adjust the height, and the second air cylinder 75 can drive the lifting device 5 to move left and right; after the button blank 100 on the conveyor belt 16 falls onto the lower mold 25 and is pressed, the height of the lifting device 5 is increased, when the second cylinder 75 drives the lifting device 5 to move leftwards, the movable plate 24 can be turned over, the buttons on the lower mold 25 can fall into the receiving tray 71, and the design is high in automation degree and convenient to use.

The lifting device 5 of the present invention comprises a hollow tube 51 welded on the top of the lower mounting seat 43, and a movable rod 52 welded on the bottom of the upper mounting seat 6, wherein the output shaft of the second cylinder 75 is connected with the outer wall of the hollow tube 51. An upper circular plate 53 and a lower circular plate 54 are slidably arranged in the inner cavity of the hollow pipe 51, and the upper circular plate 53 and the lower circular plate 54 are matched with the inner cavity of the hollow pipe 51. A rack plate 55 is fixed between the upper circular plate 53 and the lower circular plate 54, and the rack plate 55 is provided in the vertical direction. A motor seat 56 is fixed on the outer wall of the hollow tube 51, a servo motor 57 is mounted on the top of the motor seat 56 through screws, a rotating shaft 58 extending into the inner cavity of the hollow tube 51 is fixed on an output shaft of the servo motor 57, a gear 59 meshed with the rack plate 55 is fixed on the end of the rotating shaft 58 positioned in the hollow tube 51, and the bottom end of the movable rod 52 extends into the inner cavity of the hollow tube 51 and is connected with the upper circular plate 53. The rotation of the servo motor 57 can drive the gear 59 to rotate, and further drive the rack plate 55 to move up and down, and further drive the movable rod 52 to move up and down, so that the height adjustment of the lifting device 5 is realized, and the design automation degree is high.

The top of the hollow tube 51 of the present invention is fixed with an end cap 510, and the movable rod 52 passes through the end cap 510 and is slidably connected with the end cap 510, so that the movable rod 52 is prevented from shaking.

The end of the gear 59 far away from the rotating shaft 58 is fixed with a rotating shaft 500 which extends out of the hollow pipe 51 and is rotatably connected with the hollow pipe 51, so that the gear 59 is prevented from shaking.

It should be noted that the standard components used in the present invention can be purchased from the market, the special-shaped parts can be customized according to the description and the description of the drawings, the specific connection manner of each part adopts the conventional means of bolt, rivet, welding, etc. mature in the prior art, the machines, parts and equipment all adopt the conventional models in the prior art, and the inventor does not need to describe in detail here.

While one embodiment of the present invention has been described in detail, the present invention is only a preferred embodiment of the present invention and should not be construed as limiting the scope of the present invention. All equivalent changes and modifications made within the scope of the present invention shall fall within the scope of the present invention.

Claims

1. The utility model provides a mechanical automation system spiral-lock is put, includes the bottom plate, turn right from a left side in the top of bottom plate and be fixed with support column and support in proper order, the outer wall that the support column is close to the top is fixed with vibrating motor, be fixed with the feed cylinder on vibrating motor's the output shaft, install the conveyer belt on the support, the bottom export of feed cylinder is located the left end top of conveyer belt, its characterized in that: a left pillar and a right pillar are fixed on the top of the bottom plate on the right side of the support, a top plate is fixed on the top of each of the left pillar and the right pillar, a movable plate is arranged on the top of the top plate, the top plate on the right side is movably connected with the movable plate, a lower die is fixed above the movable plate, an upper die is connected above the lower die through a first air cylinder, and the lower die is arranged on the right lower side of the right end of the conveyor belt; a connecting plate is fixed between the left pillar and the right pillar, a lower guide rail is fixed at the top of the connecting plate, at least two lower guide wheels are arranged in the lower guide rail in a sliding manner, a lower mounting seat is mounted at the top of each guide wheel, a lifting device is fixed at the top of each lower mounting seat, an upper mounting seat is fixed at the top of each lifting device, an upper guide rail is fixed at the bottom of each movable plate, an upper guide wheel which is in sliding connection with the upper guide rail is fixed at the top of each upper mounting seat, and a material receiving disc is fixed on the outer wall of the right pillar; and a second cylinder is fixed on the inner wall of the left support, and an output shaft of the second cylinder is connected with the lifting device.

2. The mechanical automated buckle making device of claim 1, wherein: and a reinforcing plate connected with the bottom of the material receiving disc is fixed on the outer wall of the right support.

3. The mechanical automated buckle making device of claim 2, wherein: elevating gear is including fixing the hollow tube at mount pad top down, fixing go up the movable rod of mount pad bottom, it has plectane and lower plectane to slide in the inner chamber of hollow tube to be provided with, go up the plectane and be fixed with the rack board down between the plectane, the outer wall of hollow tube is fixed with the motor cabinet, servo motor is installed at the top of motor cabinet, be fixed with on servo motor's the output shaft and extend to rotation axis in the hollow tube inner chamber, the rotation axis is located be fixed with on the end in the hollow tube with the gear of rack board meshing, the bottom of movable rod extends to in the inner chamber of hollow tube and with it connects to go up the plectane.

4. The mechanical automated buckle making device of claim 3, wherein: an end cover is fixed at the top of the hollow pipe, and the movable rod penetrates through the end cover and is in sliding connection with the end cover.

5. The mechanical automated buckle making device of claim 3, wherein: and a rotating shaft which extends out of the hollow pipe and is rotatably connected with the hollow pipe is fixed at the end of the gear far away from the rotating shaft.

6. The mechanical automated buckle making device of claim 1, wherein: the number of the lower guide wheels is two.

7. The mechanical automated buckle making device of claim 3, wherein: and an output shaft of the second cylinder is connected with the outer wall of the hollow pipe.

8. The mechanical automated buckle making device of claim 3, wherein: the rack plate is arranged along the vertical direction.

9. The mechanical automated buckle making device of claim 3, wherein: the upper circular plate and the lower circular plate are matched with the inner cavity of the hollow pipe.