CN116373452B

CN116373452B - A gilding press tilting mechanism for carton printing

Info

Publication number: CN116373452B
Application number: CN202310270013.XA
Authority: CN
Inventors: 邓凌丰
Original assignee: Dongtai Shiheng Machinery Technology Co ltd
Current assignee: Dongtai Shiheng Machinery Technology Co ltd
Priority date: 2023-03-20
Filing date: 2023-03-20
Publication date: 2023-11-03
Anticipated expiration: 2043-03-20
Also published as: CN116373452A

Abstract

The application discloses a stamping machine turnover mechanism for carton printing, which comprises a supporting platform, wherein a group of first movable grooves communicated to the outside of the supporting platform are respectively formed in two sides of an inner cavity of the supporting platform, a movable table is movably connected in the first movable grooves through pin shafts, a hydraulic cylinder is fixedly arranged on the left side of the inside of the supporting platform, a driving motor is fixedly arranged on one side of the outside of the supporting platform, and a limiting clamping plate in transmission connection with the other side of the movable table through another group of pin shafts is fixedly arranged in the middle of the top end of the first supporting frame. According to the turnover mechanism of the stamping machine for printing the paper boxes, provided by the application, for the arrangement of the supporting platform, the movable table, the first supporting frame and the upper structure of the supporting platform, the paper boxes on the movable table are turned by utilizing the reciprocating rotation action of the first supporting frame, and the positions of the paper boxes before and after turning are not changed, so that the precision of the stamping equipment for stamping the paper boxes is effectively improved.

Description

A gilding press tilting mechanism for carton printing

Technical Field

The application relates to the technical field of gold stamping turnover equipment, in particular to a gold stamping machine turnover mechanism for paper box printing.

Background

The gold stamping is a process for forming special metal effect on the surface of a printing stock by using a hot-pressing transfer technology, and has wide application prospect because the gold stamping process can be applied to most products, wherein when the surface of a paper box is processed by using the gold stamping process, a turnover mechanism is required to be configured in the existing gold stamping equipment in order to ensure better aesthetic property, and to realize double-sided gold stamping operation of the paper box in one assembly process;

in China patent document (CN 206384516U), a plate overturning mechanism of a plate conveying line is provided, and the overturning action of the plate on the conveying line can be realized by utilizing the rotating action of an upper bracket 7 of the plate overturning mechanism, but the overturning mode ensures that the plate is not positioned at the same position after overturning and the position accuracy of the plate before and after overturning is poor under the inertia action of the plate during rotation;

in the chinese patent document (CN 204508301U), a plate turnover mechanism capable of realizing accurate positioning is provided, and the turnover operation of the plate thereon can be realized by using the ring mechanism thereon, but in the gold stamping process, a certain pressure needs to be applied to the plate, so that a supporting platform needs to be arranged at the bottom of the turnover plate, and the supporting platform turned over in the patent document is further caused to rotationally move to the top of the plate, so that the gold stamping process cannot be implemented, and the applicability and reliability are poor;

therefore, there is a need for a turnover mechanism for a gold stamping device, so as to solve the drawbacks of the conventional turnover mechanism in the gold stamping device.

Disclosure of Invention

The application provides a turnover mechanism of a stamping machine for printing paper boxes, which has the advantages that the front and rear positions of the turnover mechanism are not changed after the paper boxes are turned over, so that the precision of a double-sided stamping process after one-time assembly of the turnover mechanism is higher, and a support can be automatically formed at the bottom of the turnover mechanism after the turnover mechanism is turned over, so that the problem that in the existing turnover mechanism, or the turned-over plates are not in the same position, the position precision before and after the turnover is poorer is solved; or the supporting structure at the bottom of the plate can rotate along with the plate to move to the top of the plate, so that the gold stamping process can not be performed.

In order to achieve the above purpose, the application adopts the following technical scheme: a gilding press tilting mechanism for carton printing, includes supporting platform, a set of first movable groove that communicates to its outside is offered respectively to supporting platform inner chamber's both sides, and has the movable platform through round pin axle swing joint in the inside of first movable groove, the inside left side fixed mounting of supporting platform has the pneumatic cylinder, the outside one side fixed mounting of supporting platform has driving motor, driving motor output shaft surface's both sides respectively fixed mounting have a set of first support frame, the middle part fixed mounting on first support frame top has the spacing cardboard that forms transmission connection with one side of movable platform through another set of round pin axle to a set of first logical groove and second logical groove have been offered respectively at the left and right sides of spacing cardboard.

Further, the driving motor drives the output shaft of the first support frame to be flush with the bottom end of the supporting platform, so that when the first support frame is driven to rotate to an initial state, the first support frame can be in a parallel state with the supporting platform, and the limiting clamping plate on the first support frame is mutually overlapped with the first movable groove on the supporting platform, so that the movable table on the first support frame is ensured to be in a relatively horizontal state.

Further, the width of the first through groove on the limiting clamping plate is equal to the sum of the length of the movable table driven by the hydraulic cylinder to move rightwards and the diameter of the pin shaft on the movable table.

Further, the right side on supporting platform top is offered and is crossed the second movable groove with the extension line of movable trace and driving motor's axis, and has the second support frame at the inside swing joint in second movable groove, the middle part and the one side pin joint of first support frame of second support frame, one side fixed mounting of second support frame bottom has the supporting shoe to a set of draw-in groove that holds supporting platform side arm has been seted up respectively in the both sides of supporting shoe.

Further, in this technical scheme, one side of supporting platform outside is equipped with control mechanism, control mechanism includes the loose axle that forms transmission connection with the hydraulic motor of fixed mounting at the outside opposite side of supporting platform, and the surface activity of loose axle has cup jointed fixed axle sleeve of fixed mounting on the supporting platform side, fixed axle sleeve and loose axle divide into I, II and the III three levels of staggering each other along the direction of driving motor output shaft axis, and are equipped with a set of first conductive block and second conductive block respectively on the surface of the loose axle of I level and II level, and are equipped with a set of first conductive ring and second conductive ring respectively on the inner wall of the fixed axle sleeve of I level and II level.

Further, the first conductive block and the first conductive ring rotate clockwise through an external control system and a power supply regulation driving motor, the second conductive block and the second conductive ring rotate anticlockwise through the external control system and the power supply regulation driving motor, further the overturning action of the movable table and the upper paper box of the movable table is completed in one reciprocating rotation period, the mutual rotation superposition angles between the first conductive block and the first conductive ring and between the second conductive block and between the first conductive ring and the second conductive ring are 60 degrees, and the angles of adjacent bevel edge connecting lines between the first conductive block and the second conductive block and between the first conductive ring and the second conductive ring are the same and are both larger than 60 degrees.

Further, a group of openings A and B are arranged on the outer surface of the third layer in the movable shaft and are respectively communicated with two oil receiving ports in the hydraulic cylinder and an external hydraulic pump station so as to always drive the hydraulic motor and the movable shaft on the hydraulic motor to rotate, and a through hole c, a through hole d and a through hole f positioned between the through holes are arranged in the third layer in the fixed shaft sleeve, wherein the through hole f is an oil inlet of the hydraulic motor and is communicated with an oil inlet of the hydraulic motor, and the through hole c and the through hole d are oil outlets of the hydraulic motor and are communicated with oil outlets of the hydraulic motor.

Further, when the movable shaft rotates along with the hydraulic motor and the notch A is communicated with the through hole f, the notch B is communicated with the through hole d, the notch A is an oil inlet of the hydraulic cylinder, the notch B is an oil outlet of the hydraulic cylinder, and the hydraulic cylinder is forced to move to the right side;

and when the notch B is communicated with the through hole f, the notch A is communicated with the through hole c, the notch B is an oil inlet of the hydraulic cylinder, the notch A is an oil outlet of the hydraulic cylinder, and the hydraulic cylinder is forced to move leftwards.

1. According to the turnover mechanism of the stamping machine for printing the paper boxes, provided by the application, for the arrangement of the supporting platform, the movable table, the first supporting frame and the upper structure of the supporting platform, the paper boxes on the movable table are turned by utilizing the reciprocating rotation action of the first supporting frame, and the positions of the paper boxes before and after turning are not changed, so that the precision, stability and reliability of the stamping equipment in the process of stamping the paper boxes are effectively improved.

2. According to the turnover mechanism of the stamping machine for printing the paper boxes, provided by the application, the second support frame and the upper structure of the second support frame are arranged, so that the second support frame can act along with the reciprocating rotary action of the first support frame, and can automatically rotate and move to the bottom of the movable table when the turnover action of the paper boxes is completed, so that the paper boxes clamped on the second support frame can be effectively supported, the precision of the stamping equipment in the process of stamping the paper boxes is further improved, and the applicability and reliability are higher.

3. According to the turnover mechanism of the stamping machine for paper box printing, disclosed by the application, for the control mechanism and the arrangement of the upper structure of the turnover mechanism, linkage control can be formed between the hydraulic cylinder and the driving motor according to specific steps, and the turnover mechanism has a wider application range to the environment, higher controllability and longer service life due to the design of purely mechanical structure control.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description, serve to explain the principles of the application.

The disclosure may be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic diagram of the structure of the present application;

FIG. 2 is a front view of the structure of the present application;

FIG. 3 is a schematic view of the support platform and the structure thereof according to the present application;

FIG. 4 is a schematic structural view of a first support frame according to the present application;

FIG. 5 is a schematic view of the structure of the movable table of the present application;

FIG. 6 is a cross-sectional view of the control mechanism of the present application;

FIG. 7 is a schematic view of a fluid flow portion of the structural control mechanism of the present application in a first state;

FIG. 8 is a partial schematic view of the fluid flow of the structural control mechanism of the present application in a second state;

fig. 9 is a schematic diagram of the structure of the present application.

In the figure: 1. a support platform; 2. a first movable groove; 3. a pin shaft; 4. a movable table; 5. a hydraulic cylinder; 6. a hydraulic motor; 7. a driving motor; 8. a first support frame; 9. a second support frame; 10. a second movable groove; 11. a support block; 12. a clamping groove; 13. a limiting clamping plate; 14. a first through groove; 15. a second through slot; 16. a control mechanism; 17. fixing the shaft sleeve; 18. a movable shaft; 19. a first conductive block; 20. a second conductive block; 21. a first conductive ring; 22. and a second conductive ring.

Description of the embodiments

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

As shown in fig. 1-2, a turnover mechanism of a stamping machine for printing paper boxes comprises a supporting platform 1 fixedly installed on the stamping equipment, wherein two sides of an inner cavity of the supporting platform 1 are respectively provided with a group of first movable grooves 2 communicated to the outside of the supporting platform, as shown in fig. 5, the inside of the first movable grooves 2 is movably connected with a movable table 4 through pin shafts 3, a groove for clamping the paper boxes is formed in the inner wall of the movable table 4, a hydraulic cylinder 5 capable of pushing the movable table 4 to move to the right side is fixedly installed on the left side of the inside of the supporting platform 1, one side of the outside of the supporting platform 1 is fixedly provided with a driving motor 7, two sides of the outer surface of an output shaft of the driving motor 7 are respectively fixedly provided with a group of first supporting frames 8, as shown in fig. 4, the middle part of the top end of each first supporting frame 8 is fixedly provided with a group of limiting clamping plates 13 in transmission connection with one side of the movable table 4 through another group of pin shafts 3, and a group of first through grooves 14 and second through grooves 15 for accommodating the pin shafts 3 on the movable table 4 to move are respectively formed at the left and right ends and the limiting clamping plates 13;

as shown in fig. 9, the driving motor 7 is further utilized to drive the first support frame 8 to rotate to a certain angle along the pointer, so that the pin shaft 3 on one side of the movable table 4 moves along the track of the first movable slot 2 on the support platform 1, and the pin shaft 3 on the other side moves along the track of the limit clamping plate 13 on the first support frame 8 until the pin shaft 3 is converted from a state of tilting to the right side from a state of tilting to the left side, then the driving motor 7 is reversely started to drive the first support frame 8 to rotate anticlockwise to restore to an initial state, and the hydraulic cylinder 5 is utilized to drive the movable table 4 to move to the right side, so that the movement track of the pin shaft 3 on the movable table 4 is forced to be converted, and the overturning action of the paper box clamped on the movable table 4 is completed.

As shown in fig. 2, in the present technical solution, the driving motor 7 drives the output shaft of the first support frame 8 to rotate to be level with the bottom end of the supporting platform 1, so that when the first support frame 8 is driven to rotate to an initial state, the first support frame 8 can be kept in a parallel state with the supporting platform 1, and the limit clamping plate 13 on the first support frame 8 is mutually overlapped with the first movable slot 2 on the supporting platform 1, so as to ensure that the movable table 4 on the first support frame is in a relatively horizontal state, and ensure the precision of the gold stamping process for the paper box on the first support frame.

As shown in fig. 2 and fig. 4, in the present technical solution, the width of the first through slot 14 on the limiting clamping plate 13 is equal to the sum of the length of the hydraulic cylinder 5 driving the movable table 4 to move to the right and the diameter of the pin shaft 3 on the movable table, so as to ensure that the phenomenon that the limiting clamping plate 13 will not interfere with the pin shaft 3 on the movable table 4 in the initial stage of the clockwise rotation motion of the driving motor 7 driving the first supporting frame 8.

As shown in fig. 1, in the present technical solution, a second movable slot 10 intersecting with an extension line of a movable track and a central axis of a driving motor 7 is formed on a right side of a top end of a supporting platform 1, a second supporting frame 9 is movably connected in the second movable slot 10, a middle part of the second supporting frame 9 is pinned with one side of a first supporting frame 8, a supporting block 11 is fixedly mounted on one side of a bottom end of the second supporting frame 9, and a set of clamping slots 12 for accommodating side arms of the supporting platform 1 are respectively formed on two sides of the supporting block 11, so that the second supporting frame 9 and the supporting block 11 thereon can be driven to rotate along with the first supporting frame 8 in a process of driving the first supporting frame 8 to rotate, and when the first supporting frame 8 rotates to an initial state, the second supporting frame 9 and the supporting block 11 thereon are forced to keep a horizontal state, and then after a paper box clamped on the movable table 4 completes a turnover operation, an effective support can be formed at a bottom of the paper box.

As shown in fig. 3 and 6, in the present technical solution, a control mechanism 16 is disposed on one side of the outside of the supporting platform 1, the control mechanism 16 includes a movable shaft 18 that is in transmission connection with a hydraulic motor 6 fixedly mounted on the other side of the outside of the supporting platform 1, and the outer surface of the movable shaft 18 is movably sleeved with a fixed shaft sleeve 17 fixedly mounted on the side surface of the supporting platform 1, the fixed shaft sleeve 17 and the movable shaft 18 are divided into three layers i, ii and iii that are staggered with each other along the direction of the output shaft axis of the driving motor 7, and a set of first conductive blocks 19 and second conductive blocks 20 are respectively disposed on the outer surfaces of the movable shaft 18 of the first layer and the second layer, and a set of first conductive rings 21 and second conductive rings 22 are respectively disposed on the inner walls of the fixed shaft sleeve 17 of the first layer and the second layer.

In this technical scheme, first conducting block 19 and first conducting ring 21 are through external control system and power regulation driving motor 7 clockwise rotation, and second conducting block 20 and second conducting ring 22 are through external control system and power regulation driving motor 7 anticlockwise rotation, and then accomplish the upset action to movable table 4 and go up the carton thereof when a reciprocal rotation cycle, and the angle of mutual rotatory coincidence between first conducting block 19 and first conducting ring 21 and second conducting block 20 and second conducting ring 22 is 60, and the angle of adjacent hypotenuse link between first conducting block 19 and second conducting block 20 and first conducting ring 21 and second conducting ring 22 is the same and all is greater than 60.

As shown in fig. 6, in the present technical solution, a set of openings a and B are provided on the outer surface of the third layer in the movable shaft 18, and are respectively connected with two oil receiving ports in the hydraulic cylinder 5 and an external hydraulic pump station, so as to always drive the hydraulic motor 6 and the movable shaft 18 thereon to rotate, while a through hole c, a through hole d and a through hole f located therebetween are provided in the third layer in the fixed shaft sleeve 17, wherein the through hole f is an oil inlet and is connected with an oil inlet in the hydraulic motor 6, and the through hole c and the through hole d are oil outlets and are connected with an oil outlet in the hydraulic motor 6.

In the present technical solution, as shown in fig. 7 to 8, when the movable shaft 18 rotates along with the hydraulic motor 6 and the opening a is communicated with the through hole f, the opening B is communicated with the through hole d, the opening a is an oil inlet of the hydraulic cylinder 5, the opening B is an oil outlet of the hydraulic cylinder 5, and the hydraulic cylinder 5 is forced to move to the right side;

and when the opening B is communicated with the through hole f, the opening A is communicated with the through hole c, the opening B is an oil inlet of the hydraulic cylinder 5, the opening A is an oil outlet of the hydraulic cylinder 5, and the hydraulic cylinder 5 is forced to move leftwards.

Claims

1. Gilding press tilting mechanism for carton printing, including supporting platform (1), its characterized in that: a group of first movable grooves (2) communicated to the outside of the inner cavity of the supporting platform (1) are respectively formed in two sides of the inner cavity of the supporting platform (1), a movable table (4) is movably connected in the first movable grooves (2) through a pin shaft (3), a hydraulic cylinder (5) is fixedly arranged on the left side of the inside of the supporting platform (1), a driving motor (7) is fixedly arranged on one side of the outside of the supporting platform (1), a group of first supporting frames (8) are respectively and fixedly arranged on two sides of the outer surface of an output shaft of the driving motor (7), a limiting clamping plate (13) in transmission connection with one side of the movable table (4) through another group of pin shafts (3) is fixedly arranged in the middle of the top end of the first supporting frames (8), and a group of first through grooves (14) and second through grooves (15) are respectively formed in the left end and the right end of the limiting clamping plate (13);

the right side on supporting platform (1) top is offered with the extension line of movable trace and second movable groove (10) that the axis of driving motor (7) is crossing, and has second support frame (9) at the inside swing joint in second movable groove (10), the middle part of second support frame (9) and one side pin joint of first support frame (8), one side fixed mounting of second support frame (9) bottom has supporting shoe (11) to set up draw-in groove (12) of holding supporting platform (1) side arm respectively in the both sides of supporting shoe (11).

2. The turnover mechanism of a stamping machine for paper box printing according to claim 1, wherein the driving motor (7) drives the output shaft of the first support frame (8) to rotate to be flush with the bottom end of the supporting platform (1), so that when the first support frame (8) is driven to rotate to an initial state, the first support frame (8) can be kept in a parallel state with the supporting platform (1), and the limit clamping plate (13) on the first support frame (8) is mutually overlapped with the first movable groove (2) on the supporting platform (1), so that the movable table (4) on the limit clamping plate is ensured to be in a relatively horizontal state.

3. The turnover mechanism of the stamping machine for paper box printing according to claim 2, wherein the width of the first through groove (14) on the limiting clamping plate (13) is equal to the sum of the length of the movable table (4) driven by the hydraulic cylinder (5) to move to the right side and the diameter of the pin shaft (3) on the movable table.

4. The turnover mechanism of the stamping machine for paper box printing according to claim 1, wherein one side of the outer part of the supporting platform (1) is provided with a control mechanism (16), the control mechanism (16) comprises a movable shaft (18) which is in transmission connection with a hydraulic motor (6) fixedly installed on the other side of the outer part of the supporting platform (1), the outer surface of the movable shaft (18) is movably sleeved with a fixed shaft sleeve (17) fixedly installed on the side surface of the supporting platform (1), the fixed shaft sleeve (17) and the movable shaft (18) are divided into three layers I, II and III which are staggered with each other along the direction of the axis of an output shaft of the driving motor (7), the outer surface of the movable shaft (18) of the first layer is provided with a first conductive block (19), the outer surface of the movable shaft (18) of the second layer is provided with a second conductive block (20), the inner wall of the fixed shaft sleeve (17) of the first layer is provided with a first conductive ring (21), and the inner wall of the fixed shaft sleeve (17) of the second layer is provided with a second conductive ring (22).

5. The turnover mechanism of a stamping machine for printing paper boxes according to claim 4, wherein the first conductive block (19) and the first conductive ring (21) rotate clockwise through an external control system and a power regulation driving motor (7), the second conductive block (20) and the second conductive ring (22) rotate anticlockwise through the external control system and the power regulation driving motor (7), the mutual rotation superposition angles between the first conductive block (19) and the first conductive ring (21) and between the second conductive block (20) and the second conductive ring (22) are 60 degrees, and the adjacent bevel connection angles between the first conductive block (19) and the second conductive block (20) and between the first conductive ring (21) and the second conductive ring (22) are the same and are larger than 60 degrees.

6. The turnover mechanism of a gilding press for carton printing according to claim 5, characterized in that a set of openings a and B are provided on the outer surface of the third layer in the movable shaft (18) and are respectively communicated with two oil receiving ports in the hydraulic cylinder (5) and an external hydraulic pump station, while a through hole c, a through hole d and a through hole f located therebetween are provided inside the third layer in the fixed shaft sleeve (17), wherein the through hole f is an oil inlet communicated with an oil inlet in the hydraulic motor (6), and the through hole c and the through hole d are oil outlets communicated with an oil outlet in the hydraulic motor (6).

7. The turnover mechanism of a gilding press for paper box printing according to claim 6, wherein when the movable shaft (18) rotates along with the hydraulic motor (6) and the opening a is communicated with the through hole f, the opening B is communicated with the through hole d, the opening a is an oil inlet of the hydraulic cylinder (5), the opening B is an oil outlet of the hydraulic cylinder (5), and the hydraulic cylinder (5) is forced to move to the right side;

and when the opening B is communicated with the through hole f, the opening A is communicated with the through hole c, the opening B is an oil inlet of the hydraulic cylinder (5), the opening A is an oil outlet of the hydraulic cylinder (5), and the hydraulic cylinder (5) is forced to move leftwards.