CN219749222U - Down-pressure thermoprint cross cutting machine with booster mechanism - Google Patents

Abstract

The utility model discloses a down-pressing type thermoprinting die-cutting machine with a pressurizing mechanism, wherein the pressurizing mechanism is arranged on a thermoprinting die-cutting unit, and the thermoprinting die-cutting unit also comprises a fixed platform, a supporting and fixing plate and a driving assembly; the fixed platform is arranged on the upright post of the frame; the support fixing plate is arranged on the upright post of the frame and positioned above the fixing platform; the driving component is arranged on the supporting and fixing plate; the pressurizing mechanism is connected with the fixed platform and the movable platform and is used for increasing pressure on the movable platform. According to the utility model, the pressurizing mechanism is additionally arranged on the hot stamping die cutting unit of the hot stamping die cutting machine, so that the hot stamping die cutting pressure of the hot stamping die cutting process can be effectively improved, more hot stamping die cutting process requirements can be met, the pressure can be accurately regulated, and the pressure consistency in repeated hot stamping die cutting is ensured; the utility model has simple operation, can effectively save auxiliary working time, improves working efficiency and is easy to be widely applied.

Description

Down-pressure thermoprint cross cutting machine with booster mechanism

Technical Field

The utility model relates to the field of post-press equipment, in particular to a down-press type thermoprinting die-cutting machine with a pressurizing mechanism.

Background

The hot stamping die-cutting machine is mainly used for stamping the electrochemical aluminum on the printing paper, and die-cutting and indentation processing of the printing paper can be completed by installing a die-cutting and indentation cutter on a movable platform. But is limited by the pressure of the movable platform on the printing paper, the hot stamping die-cutting machine in the prior art is difficult to adapt to the requirements of more and more hot stamping die-cutting processes.

Disclosure of Invention

The utility model aims to solve the technical problem of providing a down-pressure type thermoprinting die-cutting machine with a pressurizing mechanism, and by adding the pressurizing mechanism, the pressure of the thermoprinting die-cutting process is improved, so that the machine can adapt to more thermoprinting die-cutting process requirements, and can accurately adjust the pressure and ensure the pressure consistency in repeated thermoprinting die-cutting.

In order to solve the technical problem, the utility model provides a down-pressure type thermoprinting die-cutting machine with a pressurizing mechanism, wherein the pressurizing mechanism is arranged on a thermoprinting die-cutting unit, and the thermoprinting die-cutting unit further comprises:

a fixed platform 22 fixedly mounted on the upright post of the hot stamping and cutting unit frame 1, and a steel plate 23 is mounted on the upper surface thereof;

a support fixing plate 8 mounted to the upright of the thermo-stamping die-cutting unit frame 1 and located above the fixing platform;

the driving assembly is arranged on the supporting and fixing plate 8 and is used for driving the movable platform 25 to be pressed or separated from the steel plate 23;

wherein, the pressurizing mechanism is connected with the fixed platform 22 and the movable platform 25, and is used for increasing the pressure on the movable platform 25.

Preferably, the driving assembly includes:

an upper fixing plate 6 mounted to the support fixing plate 8 through a fixing support shaft 7 and located above the support fixing plate 8;

a first servo motor 2 mounted on the upper fixed plate 6 through a first servo motor fixed plate 4, wherein a first main transmission synchronous pulley 3 is mounted on an output shaft of the first servo motor 2;

a driving plate 17 located between the upper fixing plate 6 and the supporting fixing plate 8, wherein a ball screw transmission pair 31 is installed at a central position of the driving plate, an upper portion of a screw of the ball screw transmission pair 31 is fixedly supported at a central position of the upper fixing plate 6 through a ball screw supporting bearing seat 33, a first driven synchronous pulley 5 is fixedly installed at a top of the screw, the first driving synchronous pulley 3 is connected with the first driven synchronous pulley 5, and a linear bearing 16 is installed on the driving plate 17 for the fixed supporting shaft 7 to pass through;

the movable platform 25 is connected with the driving plate 17 through a driving sleeve shaft 29.

Preferably, the bottom end of the driving sleeve 29 is connected with the movable platform 25 through a driving sleeve flange 28;

the top end of the driving sleeve shaft 29 is fixedly connected to the lower surface of the driving plate 17;

the driving sleeve shaft penetrates through the supporting and fixing plate 8 and moves up and down relative to the supporting and fixing plate 8 through the driving sleeve shaft linear bearing 30.

Preferably, the pressurizing mechanism includes:

a second servo motor 9 fixedly installed on the supporting and fixing plate 8 and positioned at the right side of the paper feeding direction, and having an output shaft provided with a second primary transmission synchronous pulley 11;

the first driving sliding rail 13 is perpendicular to the paper feeding direction, and is respectively arranged at a position close to the paper feeding port and a position close to the paper discharging port, and is arranged on the lower surface of the supporting and fixing plate 8 and positioned at the left side of the paper feeding direction, and a sliding rail screw shaft 12 of the first driving sliding rail 13 at the position close to the paper feeding port is connected with an output shaft of the second servo motor 9; a second driven synchronous pulley 32 is arranged on the rail screw shaft 12 of the first driving rail 13 close to the paper outlet, and the second driven synchronous pulley 32 is connected with the second main driving synchronous pulley 11;

the second driving sliding rail 18 is perpendicular to the paper feeding direction, is arranged at a position close to the paper feeding port and a position close to the paper discharging port, is arranged on the lower surface of the supporting and fixing plate 8 and is positioned on the right side of the paper feeding direction, the second driving sliding rail 18 at the paper feeding port is connected with the first driving sliding rail 13 at the paper feeding port through a driving sliding rail connecting shaft 26 and can synchronously rotate, and the second driving sliding rail 18 at the paper discharging port is connected with the first driving sliding rail 13 at the paper feeding port through a driving sliding rail connecting shaft 26 and can synchronously rotate;

the left toggle rod 27 is positioned at the left side of the paper feeding direction and is respectively arranged at a position close to the paper feeding port and a position close to the paper discharging port, the top end of the left toggle rod 27 is connected with the first driving sliding rail sliding table 14 of the first driving sliding rail 13 through an upper toggle rod shaft and connecting plate assembly 15, and the bottom end of the left toggle rod 27 is connected with the movable platform 25 through a lower toggle rod shaft and connecting plate assembly 21;

the right toggle rod 20 is positioned on the right side of the paper feeding direction and is respectively arranged at a position close to the paper feeding port and a position close to the paper discharging port, the top of the right toggle rod 20 is connected with the second driving sliding rail sliding table 19 of the second driving sliding rail 18 through an upper toggle rod shaft and connecting plate assembly 15, and the bottom end of the right toggle rod 20 is connected with the movable platform 25 through a lower toggle rod shaft and connecting plate assembly 21;

when the movable platform 25 is pressed against the steel plate 23, the axial directions of the left toggle rod 27 and the right toggle rod 20 form an included angle smaller than 3 ° with the vertical direction of the movable platform 25.

Preferably, the fixed support shafts 7 are disposed at four corners of the support fixing plate 8, and two diagonal fixed support shafts 7 are symmetrically distributed centering around the center of the support fixing plate 8.

Preferably, the second servo motor 9 is mounted to the support fixing plate 8 through a second servo motor fixing bracket 10.

Preferably, the lower surface of the movable platform 25 is mounted with an thermo-stamping die 24.

According to the utility model, the pressurizing mechanism is additionally arranged on the hot stamping die cutting unit of the hot stamping die cutting machine, so that the hot stamping die cutting pressure of the hot stamping die cutting process can be effectively improved, more hot stamping die cutting process requirements can be met, the pressure can be accurately regulated, and the pressure consistency in repeated hot stamping die cutting is ensured; the utility model has simple operation, can effectively save auxiliary working time, improves working efficiency and is easy to be widely applied.

Drawings

In order to more clearly illustrate the technical solutions of the present utility model, the following brief description of the drawings is given for the purpose of the present utility model, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings can be obtained according to these drawings without the need for inventive work for a person skilled in the art.

FIG. 1 is a schematic view of a down-press hot stamping die-cutting machine with a pressurizing mechanism according to an embodiment of the present utility model, wherein an arrow shows a paper feeding direction;

FIG. 2 is a schematic view of a stamping die unit structure of an embodiment of a down-press type stamping die-cutting machine with a pressurizing mechanism according to the present utility model;

FIG. 3 is a schematic view of a paper feed side of a hot stamping die cutting unit of an embodiment of a down-press type hot stamping die cutting machine with a pressurizing mechanism according to the present utility model, wherein a movable platform is pressed on a steel plate;

fig. 4 is a schematic view of a paper feeding side of a thermo-stamping die-cutting unit of an embodiment of the present utility model with a pressing down thermo-stamping die-cutting machine having a pressurizing mechanism, wherein a movable platen is in a raised state.

In the figure, a: an electrochemical aluminum foil conveying and recycling unit; b: a hot stamping and cutting unit; 1: a hot stamping die-cutting unit frame 1;2: a first servo motor; 3: a first primary drive synchronous pulley; 4: a first servo motor fixing plate; 5: a first driven synchronous pulley; 6: an upper fixing plate; 7: fixing a supporting shaft; 8: a supporting and fixing plate; 9: a second servo motor; 10: a second servo motor fixing bracket; 11: a second primary drive synchronous pulley; 12: a slide rail screw shaft; 13: a first drive rail; 14: the first driving sliding rail sliding table; 15: an upper elbow shaft and a connecting plate assembly; 16: a linear bearing; 17: a driving plate; 18: the second driving slide rail; 19: the second driving sliding rail sliding table; 20: a right toggle lever; 21: a lower elbow shaft and a connecting plate assembly; 22: a fixed platform; 23: a steel plate; 24: hot stamping and cutting a die; 25: a movable platform; 26: driving a slide rail connecting shaft; 27: left toggle rod; 28: driving the sleeve shaft flange; 29: driving the sleeve shaft; 30: driving a sleeve shaft linear bearing; 31: a ball screw transmission pair; 32: a second driven synchronous pulley; 33: the ball screw supports the bearing seat.

Detailed Description

The following description of the embodiments of the present utility model will be made more apparent and fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the utility model are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, there is shown a down-press type hot stamping die-cutting machine of the present utility model having a pressurizing mechanism mounted to a hot stamping die-cutting unit, the hot stamping die-cutting unit further comprising:

a fixed platform 22 fixedly mounted on the upright post of the hot stamping and cutting unit frame 1, and a steel plate 23 is mounted on the upper surface thereof;

a support fixing plate 8 mounted to the upright of the thermo-stamping die-cutting unit frame 1 and located above the fixing platform;

the driving assembly is arranged on the supporting and fixing plate 8 and is used for driving the movable platform 25 to be pressed or separated from the steel plate 23;

the pressurizing mechanism is connected with the fixed platform 22 and the movable platform 25 and is used for increasing pressure on the movable platform 25.

In the embodiment of the utility model, an electrochemical aluminum foil conveying and recycling unit A of a down-pressure type hot stamping die-cutting machine is positioned above a hot stamping die-cutting unit B, a fixed platform 22 of the hot stamping die-cutting unit is positioned at the bottom of the unit, a movable platform 25 is positioned above the fixed platform 22, and when a driving assembly drives the movable platform 25 to press on a steel plate 23, a pressurizing mechanism pressurizes the movable platform 25 to increase the hot stamping die-cutting pressure; the printing paper is placed on the steel plate 23.

In a specific embodiment, the drive assembly comprises:

an upper fixing plate 6 mounted to the support fixing plate 8 through a fixing support shaft 7 and located above the support fixing plate 8;

a first servo motor 2 mounted on the upper fixed plate 6 through a first servo motor fixed plate 4, wherein a first main transmission synchronous pulley 3 is mounted on an output shaft of the first servo motor 2;

a driving plate 17 located between the upper fixing plate 6 and the supporting fixing plate 8, wherein a ball screw transmission pair 31 is installed at a central position of the driving plate, an upper portion of a screw of the ball screw transmission pair 31 is fixedly supported at a central position of the upper fixing plate 6 through a ball screw supporting bearing seat 33, a first driven synchronous pulley 5 is fixedly installed at a top of the screw, the first driving synchronous pulley 3 is connected with the first driven synchronous pulley 5, and a linear bearing 16 is installed on the driving plate 17 for the fixed supporting shaft 7 to pass through;

the movable platform 25 is connected with the driving plate 17 through a driving sleeve shaft 29.

In this embodiment, the driving component drives the movable platform to move up and down by the following manner: the supporting and fixing plate 8 and the upper fixing plate 6 are fixed, the first servo motor 2 drives the first main transmission synchronous pulley 3 to rotate through an output shaft so as to drive the first driven synchronous pulley 5 to rotate, a screw rod of the ball screw transmission pair 31 rotates along with the first driven synchronous pulley 5, and further the ball screw transmission pair 31 drives the driving plate 17 to move up and down, and the movable platform 25 and the driving plate 17 are rigidly connected through the driving sleeve shaft 29, so that the driving plate 17 moves up and down to drive the movable platform 25 to move along with the first driven synchronous pulley 5; fig. 2 and 3 show a state in which the movable platform 25 is pressed against the steel plate 23, and fig. 4 shows a state in which the movable platform is raised.

In a specific embodiment, the bottom end of the driving sleeve 29 is connected to the movable platform 25 through a driving sleeve flange 28; the top end of the driving sleeve shaft 29 is fixedly connected to the lower surface of the driving plate 17; the driving sleeve shaft penetrates through the supporting and fixing plate 8 and moves up and down relative to the supporting and fixing plate 8 through the driving sleeve shaft linear bearing 30.

In a specific embodiment, the pressurizing mechanism includes:

a second servo motor 9 fixedly installed on the supporting and fixing plate 8 and positioned at the right side of the paper feeding direction, and having an output shaft provided with a second primary transmission synchronous pulley 11;

the first driving sliding rail 13 is perpendicular to the paper feeding direction, and is respectively arranged at a position close to the paper feeding port and a position close to the paper discharging port, and is arranged on the lower surface of the supporting and fixing plate 8 and positioned at the left side of the paper feeding direction, and a sliding rail screw shaft 12 of the first driving sliding rail 13 at the position close to the paper feeding port is connected with an output shaft of the second servo motor 9; a second driven synchronous pulley 32 is arranged on the rail screw shaft 12 of the first driving rail 13 close to the paper outlet, and the second driven synchronous pulley 32 is connected with the second main driving synchronous pulley 11;

the second driving sliding rail 18 is perpendicular to the paper feeding direction, is arranged at a position close to the paper feeding port and a position close to the paper discharging port, is arranged on the lower surface of the supporting and fixing plate 8 and is positioned on the right side of the paper feeding direction, the second driving sliding rail 18 at the paper feeding port is connected with the first driving sliding rail 13 at the paper feeding port through a driving sliding rail connecting shaft 26 and can synchronously rotate, and the second driving sliding rail 18 at the paper discharging port is connected with the first driving sliding rail 13 at the paper feeding port through a driving sliding rail connecting shaft 26 and can synchronously rotate;

the left toggle rod 27 is positioned at the left side of the paper feeding direction and is respectively arranged at a position close to the paper feeding port and a position close to the paper discharging port, the top end of the left toggle rod 27 is connected with the first driving sliding rail sliding table 14 of the first driving sliding rail 13 through an upper toggle rod shaft and connecting plate assembly 15, and the bottom end of the left toggle rod 27 is connected with the movable platform 25 through a lower toggle rod shaft and connecting plate assembly 21;

the right toggle rod 20 is positioned on the right side of the paper feeding direction and is respectively arranged at a position close to the paper feeding port and a position close to the paper discharging port, the top of the right toggle rod 20 is connected with the second driving sliding rail sliding table 19 of the second driving sliding rail 18 through an upper toggle rod shaft and connecting plate assembly 15, and the bottom end of the right toggle rod 20 is connected with the movable platform 25 through a lower toggle rod shaft and connecting plate assembly 21;

when the movable platform 25 is pressed on the steel plate 23, the axial directions of the left toggle rod 27 and the right toggle rod 20 form an included angle smaller than 3 degrees with the vertical direction of the movable platform 25; in the present embodiment, the vertical direction of the movable platform 25 is a vertical direction.

In this embodiment, in the process of moving the movable platform 25 up and down driven by the driving component, since the distance between the movable platform 25 and the supporting and fixing plate 8 needs to be in a changing state, the second servo motor 9 of the pressurizing mechanism drives the slide rail screw shaft 12 of the first driving slide rail 13 near the paper feeding port to rotate through the output shaft, so that the first driving slide rail sliding table 14 can move along the first driving slide rail 13, meanwhile, the second servo motor 9 of the pressurizing mechanism synchronously drives the second main driving synchronous pulley 11 to rotate through the output shaft, and the second driven synchronous pulley 32 rotates along with the second main driving synchronous pulley 11, so as to drive the second driving slide rail sliding table 19 to move along the second driving slide rail 18, and by setting the rotation speed of the first servo motor 2 and the second servo motor 9, the displacement component in the vertical direction in the tilting movement process of the left side toggle rod 27 and the right toggle rod 20 is equal to the distance of the movable platform 25 in the vertical direction.

In this embodiment, the pressurization of the movable platform 25 by the pressurizing mechanism is achieved by: when the driving assembly controls the movable platform 25 to press the stamping die 24 onto the printing paper of the steel plate 23, the second servo motor 9 continues to rotate, at this time, because an included angle (as shown in fig. 4, the included angle is 3 °) still exists between the axial direction and the vertical direction of the left toggle rod 27 and the right toggle rod 20, so the left toggle rod 27 and the right toggle rod 20 can still move to the vertical state along with the first driving sliding rail sliding table 14 and the second driving sliding rail sliding table 19, and during the moving process, because the space between the lower surface of the supporting fixed plate 8 and the upper surface of the movable platform 25 is limited, the left toggle rod 27 and the right toggle rod 20 can be subjected to a great force given by the supporting fixed plate 8 and the movable platform 25, and meanwhile, the left toggle rod 27 and the right toggle rod 20 react the received force to the supporting fixed plate 8 and the movable platform 25, so that the lower pressure of the movable platform 25 can be increased; in addition, since the magnitude of the pressure can be controlled by controlling the distance that the left toggle lever 27 and the right toggle lever 20 move, accurate control of the hot stamping die cutting pressure and consistency of the hot stamping die cutting pressure in the repeated hot stamping process can be achieved.

In a specific embodiment, the fixed support shafts 7 are disposed at four corners of the support fixing plate 8, and two diagonal fixed support shafts 7 are symmetrically distributed centering around the center of the support fixing plate 8.

In a specific embodiment, the second servo motor 9 is mounted to the support and fixing plate 8 by a second servo motor fixing bracket 10.

The foregoing description of the preferred embodiments of the utility model is provided for the purpose of illustration only, and is not intended to limit the utility model, as long as it is within the spirit and principles of the utility model, any modifications, equivalent substitutions, improvements, etc. should be made within the scope of the present utility model.

Claims (6)

1. A down-pressure thermo-die cutting machine with a pressurizing mechanism, characterized in that the pressurizing mechanism is mounted to a thermo-die cutting unit, the thermo-die cutting unit further comprising:

a fixed platform (22) fixedly mounted on the upright post of the hot stamping and cutting unit frame (1), and a steel plate (23) is mounted on the upper surface of the fixed platform;

a supporting and fixing plate (8) which is arranged on the upright post of the hot stamping and cutting unit frame (1) and is positioned above the fixing platform;

the driving assembly is arranged on the supporting and fixing plate (8) and is used for driving the movable platform (25) to be pressed or separated from the steel plate (23);

wherein the pressurizing mechanism is connected with the fixed platform (22) and the movable platform (25) and is used for increasing pressure on the movable platform (25);

the supercharging mechanism includes:

the second servo motor (9) is fixedly arranged on the supporting and fixing plate (8) and is positioned at the right side of the paper feeding direction, and a second main transmission synchronous pulley (11) is arranged on an output shaft of the second servo motor;

the first driving sliding rail (13) is perpendicular to the paper feeding direction, one is arranged at a position close to the paper feeding port and a position close to the paper discharging port respectively, the first driving sliding rail is arranged on the lower surface of the supporting and fixing plate (8) and is positioned at the left side of the paper feeding direction, and a sliding rail screw shaft (12) of the first driving sliding rail (13) close to the paper feeding port is connected with an output shaft of the second servo motor (9); a second driven synchronous pulley (32) is arranged on a slide rail screw shaft (12) of the first driving slide rail (13) close to the paper outlet, and the second driven synchronous pulley (32) is connected with the second main transmission synchronous pulley (11);

the second driving slide rail (18) is perpendicular to the paper feeding direction, is arranged at a position close to the paper feeding port and a position close to the paper discharging port, is arranged on the lower surface of the supporting and fixing plate (8) and is positioned on the right side of the paper feeding direction, the second driving slide rail (18) at the paper feeding port is connected with the first driving slide rail (13) at the paper feeding port through a driving slide rail connecting shaft (26) and can synchronously rotate, and the second driving slide rail (18) at the paper discharging port is connected with the first driving slide rail (13) at the paper feeding port through the driving slide rail connecting shaft (26) and can synchronously rotate;

the left toggle rod (27) is positioned at the left side of the paper feeding direction and is respectively arranged at the position close to the paper feeding port and the position close to the paper discharging port, the top end of the left toggle rod (27) is connected with a first driving sliding rail sliding table (14) of the first driving sliding rail (13) through an upper toggle rod shaft and connecting plate assembly (15), and the bottom end of the left toggle rod (27) is connected with the movable platform (25) through a lower toggle rod shaft and connecting plate assembly (21);

the right toggle rod (20) is positioned on the right side of the paper feeding direction, one right toggle rod is arranged at a position close to the paper feeding port and a position close to the paper discharging port respectively, the top of the right toggle rod (20) is connected with a second driving sliding rail sliding table (19) of the second driving sliding rail (18) through an upper toggle rod shaft and connecting plate assembly (15), and the bottom end of the right toggle rod (20) is connected with the movable platform (25) through a lower toggle rod shaft and connecting plate assembly (21);

when the movable platform (25) is pressed on the steel plate (23), the axial direction of the left toggle rod (27) and the axial direction of the right toggle rod (20) form an included angle smaller than 3 degrees with the vertical direction of the movable platform (25).

2. The down-press thermoprinting die cutter with a pressurizing mechanism according to claim 1, wherein the driving assembly comprises:

an upper fixing plate (6) which is mounted on the support fixing plate (8) through a fixed support shaft (7) and is positioned above the support fixing plate (8);

the first servo motor (2) is arranged on the upper fixed plate (6) through a first servo motor fixed plate (4), and a first main transmission synchronous pulley (3) is arranged on an output shaft of the first servo motor (2);

the driving plate (17) is positioned between the upper fixing plate (6) and the supporting fixing plate (8), a ball screw transmission pair (31) is arranged at the central position of the driving plate, the upper part of a screw rod of the ball screw transmission pair (31) is fixedly supported at the central position of the upper fixing plate (6) through a ball screw supporting bearing seat (33), a first driven synchronous pulley (5) is fixedly arranged at the top of the screw rod, the first main transmission synchronous pulley (3) is connected with the first driven synchronous pulley (5), and a linear bearing (16) is arranged on the driving plate (17) for the fixed supporting shaft (7) to pass through;

the movable platform (25) is connected with the driving plate (17) through a driving sleeve shaft (29).

3. A down-pressure thermoprinting die cutter with a pressurizing mechanism according to claim 2, wherein the bottom end of the driving sleeve (29) is connected with the movable platform (25) through a driving sleeve flange (28);

the top end of the driving sleeve shaft (29) is fixedly connected to the lower surface of the driving plate (17);

the driving sleeve shaft penetrates through the supporting and fixing plate (8) and moves up and down relative to the supporting and fixing plate (8) through the driving sleeve shaft linear bearing (30).

4. A down-pressure thermoprinting die cutter with a pressurizing mechanism according to claim 3, wherein the fixed support shafts (7) are provided at four corners of the support fixing plate (8), and two diagonal fixed support shafts (7) are symmetrically distributed centering with the center of the support fixing plate (8).

5. A down-pressure thermoprinting die cutter with a pressurizing mechanism according to claim 3, wherein the second servo motor (9) is mounted to the support fixing plate (8) by a second servo motor fixing bracket (10).

6. A down-pressure type thermo-die cutting machine with a pressurizing mechanism as claimed in claim 1, characterized in that the lower surface of the movable platform (25) is mounted with a thermo-die cutting die (24).