CN114083722A

CN114083722A - Quick die change debugging mechanism

Info

Publication number: CN114083722A
Application number: CN202111389296.7A
Authority: CN
Inventors: 刘孝东; 周毅军; 陈铭钊; 李建忠
Original assignee: Guangzhou Zhongshan Precision Technology Co Ltd
Current assignee: Guangzhou Zhongshan Precision Technology Co Ltd
Priority date: 2021-11-19
Filing date: 2021-11-19
Publication date: 2022-02-25
Anticipated expiration: 2041-11-19
Also published as: CN114083722B

Abstract

The invention discloses a quick die change debugging mechanism, which belongs to the technical field of die carrier debugging and comprises a plurality of supports arranged on a base, wherein the die carrier is fixedly arranged at the rear ends of the supports, and a first adjusting frame and a second adjusting frame are fixedly arranged at the front ends of the supports; a through groove is formed in the middle of the rear end of the die carrier, a plurality of second fixing columns penetrate through the rear end of the die carrier, a debugging seat is fixedly installed on the outer surface of each first fixing column, an inclined supporting column is fixedly installed on one side of the debugging seat, a sliding column is connected to one end, far away from the debugging seat, of each supporting column in a sliding mode, and a limiting mechanism is fixedly installed at one end, far away from the corresponding supporting column, of each sliding column; the inclined angle of the supporting columns can be forty-five degrees, and connecting lines of diagonal angles of the four supporting columns are crossed to a point limiting mechanism to be used for debugging the position of the deviated article, so that the position of the article is always kept in a normal state; the invention is used for solving the technical problem of poor die change and debugging effects in the existing scheme.

Description

Quick die change debugging mechanism

Technical Field

The invention relates to the technical field of die carrier debugging, in particular to a quick die change debugging mechanism.

Background

Fig. 1 is a conventional formwork debugging apparatus, in which a set of conventional molds are serially connected by screws, and when one of the molds fails, the entire set of molds must be completely removed, repaired or replaced, and then re-assembled and debugged, so that the debugging efficiency and accuracy are poor; in addition, the existing die carrier can not adjust objects with different specifications in a self-adaptive manner in the debugging process, so that the debugging range of the die carrier is limited.

Disclosure of Invention

The invention aims to provide a quick die change debugging mechanism, which solves the following technical problems: how to debug the position of the deviated article so that the article is always kept in a normal state; how to debug articles of different specifications; how to improve the overall die change effect of the die carrier.

The purpose of the invention can be realized by the following technical scheme:

a quick die change debugging mechanism comprises a plurality of supports arranged on a base, wherein a die frame is fixedly arranged at the rear ends of the supports, and a first adjusting frame and a second adjusting frame are fixedly arranged at the front ends of the supports;

a through groove is formed in the middle of the rear end of the die carrier, a plurality of second fixing columns penetrate through the rear end of the die carrier, a debugging seat is fixedly installed on the outer surface of each second fixing column, an inclined supporting column is fixedly installed on one side of the debugging seat, a sliding column is connected to one end, far away from the debugging seat, of each supporting column in a sliding mode, and a limiting mechanism is fixedly installed at one end, far away from the corresponding supporting column, of each sliding column; the inclined angle of the supporting columns can be forty-five degrees, and connecting lines of diagonal angles of the four supporting columns are crossed to a point limiting mechanism to be used for debugging the position of the deviated article, so that the position of the article is always kept in a normal state;

the limiting mechanism comprises a first debugging plate, a second debugging plate, a third debugging plate and a fourth debugging plate; through carrying out the modular combination with first debugging board, second debugging board, third debugging board and fourth debugging board, can debug the article of different specifications, improved the variety of die carrier debugging.

The invention has the further technical improvements that: the side surfaces of the first debugging plate, the second debugging plate and the third debugging plate, which are far away from the sliding column, are provided with a plurality of clamping columns, and the side surfaces of the second debugging plate, the third debugging plate and the fourth debugging plate, which are close to the sliding column, are provided with a plurality of clamping grooves matched with the clamping columns; the clamping columns and the clamping grooves are convenient for installing and separating the debugging plates to adjust the size of the adjusting groove.

The invention has further technical improvements that: the longitudinal section of first debugging board is fan-shaped, and the shape of second debugging board, third debugging board and fourth debugging board all is the same with first debugging plate shape, and the volume of first debugging board, second debugging board, third debugging board and fourth debugging board increases progressively.

The invention has further technical improvements that: the longitudinal section of the adjusting groove surrounded by the fourth debugging plates is circular, an electric cylinder used for driving the sliding column to move is arranged inside the debugging seat, and the electric cylinder is used for driving the sliding column to move so as to change the positions of the fourth debugging plates.

The invention has further technical improvements that: the front surface fixed mounting of support has a plurality of to run through in the first fixed column of first alignment jig and second alignment jig, and the internally mounted of first alignment jig has the first running roller of a plurality of longitudinal arrangement, and the internally mounted of second alignment jig has the second running roller of a plurality of transverse arrangement.

The invention has further technical improvements that: the outer surface of the second roller is provided with a rotary groove, the outer surface of the second roller is rotationally connected with a rotary ring, the outer surface of the rotary ring is provided with a plurality of annular grooves, and the rotary groove and the rotary ring enable the first roller and the second roller to more stably debug articles of different specifications;

be provided with first spacing groove between a plurality of first running roller, be provided with the second spacing groove between a plurality of second running roller, the first spacing groove of a plurality of and second spacing groove all are on same water flat line with the adjustment tank.

The invention has further technical improvements that: the inside horizontal installation of first alignment jig has a plurality of first spliced pole that is used for connecting first running roller, and the inside vertical installation of second alignment jig has a plurality of second spliced pole that is used for connecting the second running roller.

The invention has further technical improvements that: the upper surface of base is provided with a plurality of and is used for the gliding slide rail of support and a plurality of and is used for the fixed screw of support.

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

1. according to the invention, the position of an article can be limited and debugged by the adjusting groove formed by the first debugging plate, the second debugging plate, the third debugging plate and the fourth debugging plate, the positions of different debugging plates are changed by the arranged electric cylinders and the sliding columns, and the deviated position of the article can be quickly debugged to the original position by synchronous matching among a plurality of debugging plates, so that the efficiency and the accuracy of debugging the die carrier are improved.

2. According to the invention, the first debugging plate, the second debugging plate, the third debugging plate and the fourth debugging plate are installed and separated by clamping and separating the clamping columns and the clamping grooves, and the first debugging plate, the second debugging plate, the third debugging plate and the fourth debugging plate are combined in a modularized manner, so that the inner diameters of the adjusting grooves formed by different debugging plates are different, further, articles with different specifications can be debugged, and the debugging diversity of the die carrier is improved.

3. According to the invention, the rotating groove and the rotating ring which are arranged on the first roller and the second roller can be matched with a limiting mechanism to debug articles with different specifications, the height of the ring groove in the middle of the rotating ring is the largest, the heights of the ring grooves on two sides are sequentially reduced, the rotating ring rotates left and right and moves up and down on the second roller through the rotating groove, and the debugging device is different from the prior scheme that the outer surfaces of the first roller and the second roller are of smooth structures, the articles are easy to slip in the debugging process, and the rotating groove and the rotating ring enable the first roller and the second roller to more stably debug the articles with different specifications.

4. According to the die rack, the distance between the adjacent die racks is adjusted through the sliding rails, the plurality of supports can be positioned on the same straight line through the sliding rails, and the supports are fixed on the base through the screw holes and the bolts, so that the die racks on the plurality of supports can run independently, and the die rack can achieve a better die changing effect compared with the mode that a die needs to be integrally disassembled and assembled in the existing scheme.

Drawings

The invention will be further described with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of the prior art.

Fig. 2 is a perspective view of a rapid die change debugging mechanism according to the present invention.

Fig. 3 is a side view of the stent of the present invention.

Fig. 4 is a perspective view showing the connection of the mold frame and the holder in the present invention.

Figure 5 is a rear view of the scaffold of the present invention.

Fig. 6 is an enlarged view of the invention at a in fig. 5.

Fig. 7 is a perspective view of the connection between the debugging seat and the limiting mechanism in the invention.

Fig. 8 is a perspective view of the second roller of the present invention.

In the figure: 100. a base; 200. a support; 300. a slide rail; 400. a mold frame; 500. a first adjusting bracket; 600. a second adjusting bracket; 700. a first fixed column; 800. a first roller; 900. a second roller; 901. rotating the groove; 902. rotating the ring; 1000. a through groove; 1100. a second fixed column; 1200. a debugging seat; 1201. a support pillar; 1202. a traveler; 1203. a first debugging plate; 1204. a second debugging plate; 1205. a third debugging plate; 1206. and a fourth debugging plate.

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.

Referring to fig. 2 to 3, the present invention is a debugging mechanism for fast die change, including a plurality of brackets 200 mounted on a base 100, the number of the brackets 200 is four, a die carrier 400 is fixedly mounted at the rear end of each bracket 200, a first adjusting bracket 500 and a second adjusting bracket 600 are fixedly mounted at the front end of each bracket 200, a plurality of first fixing posts 700 penetrating through the first adjusting bracket 500 and the second adjusting bracket 600 are fixedly mounted on the front surface of each bracket 200, the first fixing posts 700 are used for connecting and fixing the first adjusting bracket 500 and the second adjusting bracket 600 with the brackets 200, and the first adjusting bracket 500 is located between the second adjusting bracket 600 and the brackets 200;

a plurality of longitudinally arranged first rollers 800 are arranged in the first adjusting frame 500, and a plurality of transversely arranged second rollers 900 are arranged in the second adjusting frame 600; a plurality of first connecting posts for connecting the first rollers 800 are horizontally arranged in the first adjusting frame 500, the first rollers 800 are rotatably connected with the first connecting posts, a plurality of second connecting posts for connecting the second rollers 900 are vertically arranged in the second adjusting frame 600, and the second rollers 900 are rotatably connected with the second connecting posts;

a first limiting groove is formed among the plurality of first rollers 800, a second limiting groove is formed among the plurality of second rollers 900, and the plurality of first limiting grooves, the second limiting grooves and the adjusting grooves are all on the same horizontal line; the articles sequentially pass through the second limiting groove, the first limiting groove and the adjusting groove to carry out rolling and pulling operation or other processing operation;

the upper surface of the base 100 is provided with a plurality of sliding rails 300 for the sliding of the brackets 200 and a plurality of screw holes for the fixing of the brackets 200, wherein the sliding rails 300 are used for adjusting the distance between the brackets 200, and can enable a plurality of brackets 200 to be positioned on the same straight line so as to better debug the position of an article, and a plurality of brackets 200 are fixed on the base 100 through the screw holes and bolts;

referring to fig. 4 to 5, a through groove 1000 is disposed in the middle of the rear end of the die carrier 400, a plurality of second fixing columns 1100 penetrate through the rear end of the die carrier 400, the number of the second fixing columns 1100 is four, the four second fixing columns 1100 are distributed and enclosed to form a square, a debugging seat 1200 is fixedly installed on the outer surface of each second fixing column 1100, the debugging seat 1200 is located in the through groove 1000, an inclined supporting column 1201 is fixedly installed on one side of the debugging seat 1200, the inclination angle of the supporting column 1201 can be forty-five degrees, the diagonal connecting lines of the four supporting columns 1201 intersect at one point, the point is set as a debugging point, a sliding column 1202 is slidably connected to one end of the supporting column 1201 away from the debugging seat 1200, and a limiting mechanism is fixedly installed at one end of the sliding column 1202 away from the supporting column 1201;

referring to fig. 6-7, the limiting mechanism includes a first debugging plate 1203, a second debugging plate 1204, a third debugging plate 1205 and a fourth debugging plate 1206, the longitudinal section of the first debugging plate 1203 is fan-shaped, the shapes of the second debugging plate 1204, the third debugging plate 1205 and the fourth debugging plate 1206 are the same as the shape of the first debugging plate 1203, and the volumes of the first debugging plate 1203, the second debugging plate 1204, the third debugging plate 1205 and the fourth debugging plate 1206 are increased progressively;

when the first debugging plate 1203, the second debugging plate 1204, the third debugging plate 1205 and the fourth debugging plate 1206 are all combined together, the longitudinal section of an adjusting groove defined by the four fourth debugging plates 1206 is circular, and the adjusting groove at the moment is used for debugging the position of an article with the minimum specification; separating the fourth debugging plate 1206, so that when the first debugging plate 1203, the second debugging plate 1204 and the third debugging plate 1205 are combined, the inner diameter of an adjusting groove surrounded by the four third debugging plates 1205 is increased, and the positions of articles with larger specifications can be debugged; similarly, after the third debugging plate 1205 and the second debugging plate 1204 are separated in sequence, the inner diameter of the adjusting groove surrounded by the four first debugging plates 1203 is the largest, so that dynamic debugging on the positions of articles with different specifications can be realized, and the debugging effect of the die carrier 400 is improved;

the side surfaces of the first debugging plate 1203, the second debugging plate 1204 and the third debugging plate 1205 far away from the sliding column 1202 are all provided with a plurality of clamping columns, the number of the clamping columns can be two, and the side surfaces of the second debugging plate 1204, the third debugging plate 1205 and the fourth debugging plate 1206 near the sliding column 1202 are all provided with a plurality of clamping grooves matched with the clamping columns; the installation and separation among the first debugging plate 1203, the second debugging plate 1204, the third debugging plate 1205 and the fourth debugging plate 1206 are realized through the clamping connection and separation of a plurality of clamping columns and clamping grooves;

the debugging seat 1200 is internally provided with an electric cylinder for driving the sliding column 1202 to move, the sliding column 1202 is driven by the electric cylinder to slide in the supporting column 1201, the positions of the first debugging plate 1203, the second debugging plate 1204, the third debugging plate 1205 and the fourth debugging plate 1206 are changed by the sliding of the sliding column 1202, and then the position of the deviated article can be debugged, so that the position of the article is always kept on a debugging point.

Referring to fig. 8, a rotating groove 901 is formed in an outer surface of a second roller 900, a rotating ring 902 is rotatably connected to the outer surface of the second roller 900, a plurality of ring grooves are formed in the outer surface of the rotating ring 902, and the structure of the first roller 800 is the same as that of the second roller 900; the number of the strip ring grooves is odd, for example, the number is 5, the height of the ring groove in the middle is the largest, the heights of the ring grooves on the two sides are reduced in sequence, the rotating ring 902 rotates left and right and moves up and down on the second roller 900 through the rotating groove 901, and the rotating ring is matched with a limiting mechanism to debug articles of different specifications.

The working principle of the invention is as follows:

the die sets 400 on the plurality of supports 200 run independently, the distance between the adjacent die sets 400 can be adjusted, the supports 200 can adjust the distance between the supports through the sliding rails 300, the plurality of supports 200 can be positioned on the same straight line through the sliding rails 300, the abnormal die sets 400 can be conveniently and quickly processed, the running of other die sets 400 cannot be influenced, the die changing effect of the die sets 400 is improved, the supports 200 are fixed on the base 100 through screw holes and bolts, and when an article sequentially passes through the second limiting groove, the first limiting groove and the adjusting groove to be rolled and pulled, if the position of the article deviates in the rolling and pulling process, the article deviates a debugging point and is contacted with the fourth debugging plate 1206; the article can be a section bar to be rolled and drawn, and when the article is deviated, two situations exist, namely the article is contacted with two adjacent fourth debugging plates 1206 on one side; the other is that the article is in contact with any one fourth debugging plate 1206;

when an article is contacted with two adjacent fourth debugging plates 1206 on one side, the adjacent fourth debugging plates 1206 are marked as a first debugging group, the adjacent fourth debugging plates 1206 on the other side are marked as a second debugging group, the sliding columns 1202 are driven to move towards debugging points through electric cylinders associated with the first debugging group, the sliding columns 1202 are driven to synchronously move towards directions far away from the debugging points through electric cylinders associated with the second debugging group, and the article is moved to the debugging points through synchronous matching of the first debugging group and the second debugging group, so that accurate debugging of the position of the offset article is realized;

when an article is in contact with any one fourth debugging plate 1206, the fourth debugging plate 1206 is marked as a first marking plate, other debugging plates are set as second marking plates, the electric cylinder associated with the first marking plate drives the sliding column 1202 to move towards the debugging point, the electric cylinder associated with the second marking plate drives the sliding column 1202 to synchronously move towards the direction far away from the debugging point, and the article is moved to the position of the debugging point through the synchronous matching of the first marking plate and the second marking plate, so that the accurate debugging of the position of the offset article is realized;

when the first debugging board 1203, the second debugging board 1204, the third debugging board 1205 and the fourth debugging board 1206 are all combined together, the inner diameter of an adjusting groove surrounded by the four fourth debugging boards 1206 is the smallest, and the adjusting groove is used for debugging the position of an article with the smallest specification; the fourth debugging plate 1206 is separated from the sliding groove on the third debugging plate 1205 through the sliding column 1202, so that when the first debugging plate 1203, the second debugging plate 1204 and the third debugging plate 1205 are combined, the inner diameter of an adjusting groove formed by the four third debugging plates 1205 is increased, and the position of an article with a larger specification can be debugged; after the third debugging plate 1205 and the second debugging plate 1204 are separated in sequence, the inner diameter of the adjusting groove surrounded by the four first debugging plates 1203 is the largest, so that dynamic debugging on the positions of articles with different specifications can be realized, and the debugging effect of the die carrier 400 is improved;

when the first roller 800 or the second roller 900 is abnormal, for example, rotation is insensitive or loose, the bracket 200 corresponding to the first roller 800 or the second roller 900 needs to be detached, so that the operation of the die carrier 400 on other brackets 200 is not affected, and the overall operation effect of the die carrier 400 is improved.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate member, or they may be connected through two or more elements. The specific meanings of the above terms in the present invention can be understood in a specific case to those of ordinary skill in the art.

While one embodiment of the present invention has been described in detail, the description is only a preferred embodiment of the present invention and should not be taken as limiting the scope of the 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. A rapid die change debugging mechanism is characterized by comprising a plurality of supports (200) arranged on a base (100), wherein a die carrier (400) is fixedly arranged at the rear ends of the supports (200), and a first adjusting frame (500) and a second adjusting frame (600) are fixedly arranged at the front ends of the supports (200);

a through groove (1000) is formed in the middle of the rear end of the die carrier (400), a plurality of second fixing columns (1100) penetrate through the rear end of the die carrier (400), a debugging seat (1200) is fixedly installed on the outer surface of each second fixing column (1100), an inclined supporting column (1201) is fixedly installed on one side of the debugging seat (1200), a sliding column (1202) is slidably connected to one end, far away from the debugging seat (1200), of each supporting column (1201), and a limiting mechanism is fixedly installed at one end, far away from the supporting column (1201), of each sliding column (1202);

the limiting mechanism comprises a first debugging plate (1203), a second debugging plate (1204), a third debugging plate (1205) and a fourth debugging plate (1206).

2. The rapid die change debugging mechanism of claim 1, wherein a plurality of clamping posts are arranged on the side surfaces of the first debugging plate (1203), the second debugging plate (1204) and the third debugging plate (1205) far away from the sliding post (1202), and a plurality of clamping grooves matched with the clamping posts are arranged on the side surfaces of the second debugging plate (1204), the third debugging plate (1205) and the fourth debugging plate (1206) close to the sliding post (1202).

3. The rapid die change debugging mechanism of claim 2, wherein the longitudinal section of the first debugging plate (1203) is fan-shaped, the shapes of the second debugging plate (1204), the third debugging plate (1205) and the fourth debugging plate (1206) are the same as that of the first debugging plate (1203), and the volumes of the first debugging plate (1203), the second debugging plate (1204), the third debugging plate (1205) and the fourth debugging plate (1206) are increased progressively.

4. The rapid die change debugging mechanism according to claim 1, wherein the longitudinal section of the adjusting groove defined by the fourth debugging plates (1206) is circular, and an electric cylinder for driving the sliding column (1202) to move is installed inside the debugging seat (1200).

5. The rapid die change debugging mechanism according to claim 1, wherein a plurality of first fixing columns (700) penetrating through the first adjusting frame (500) and the second adjusting frame (600) are fixedly installed on the front surface of the bracket (200), a plurality of longitudinally arranged first rollers (800) are installed inside the first adjusting frame (500), and a plurality of transversely arranged second rollers (900) are installed inside the second adjusting frame (600).

6. The rapid die change debugging mechanism according to claim 1, wherein the outer surface of the second roller (900) is provided with a rotating groove (901), the outer surface of the second roller (900) is rotatably connected with a rotating ring (902), and the outer surface of the rotating ring (902) is provided with a plurality of ring grooves.

7. The rapid die change debugging mechanism according to claim 5, wherein a first limiting groove is arranged between a plurality of first rollers (800), a second limiting groove is arranged between a plurality of second rollers (900), and the plurality of first limiting grooves and the plurality of second limiting grooves are all on the same horizontal line with the adjusting groove.

8. The rapid die change debugging mechanism according to claim 1, wherein a plurality of first connecting columns for connecting the first rollers (800) are horizontally installed inside the first adjusting bracket (500), and a plurality of second connecting columns for connecting the second rollers (900) are vertically installed inside the second adjusting bracket (600).

9. The rapid die change debugging mechanism according to claim 1, wherein the upper surface of the base (100) is provided with a plurality of sliding rails (300) for sliding the bracket (200) and a plurality of screw holes for fixing the bracket (200).