CN115070866A - Die-cutting machine receiving device for optical composite membrane - Google Patents

Abstract

The invention relates to the technical field of die cutting equipment, and discloses a receiving device of a die cutting machine for an optical composite membrane, which comprises a base, wherein a support frame is fixedly arranged at the position, close to one end, of the top of the base, a rotating shaft is movably sleeved at the position, close to the top, of one side of the support frame, the output end of a laser receiver is connected with the input end of a cutter in a signal connection mode, so that the cutter runs and separates a membrane plate connected with an auxiliary driving roller, the cut membrane plate is driven by the main driving roller to continuously move, corresponding holes are in a corresponding state after the two membrane plates are adhered, the cutting area is also kept in a corresponding state, the cutting area at the top of the membrane plate after receiving is ensured to be corresponding to the lower knife position of the cutting machine, the automatic receiving function is realized, and the traditional equipment needs to be shut down and manually carry out receiving operation, resulting in complicated operation and inconvenient operation, and improving the automation of the device.

Description

Die-cutting machine receiving device for optical composite membrane

Technical Field

The invention relates to the technical field of die cutting equipment, in particular to a receiving device of a die cutting machine for an optical composite membrane.

Background

The optical composite membrane is an optical material with a wide application range, can play various roles of filtering, refracting, reflecting and polarizing, and in the production process of the optical composite membrane, a finished optical composite membrane needs to be cut, so that a membrane with a small area is formed.

Although current connect the material mode operation to get up comparatively simply, connect the material in-process to need to shut down equipment, influence production efficiency to manual operation has certain limitation, and occupies more labours, has improved manufacturing cost, and to this, this application file provides an optics is cross cutting machine receiving device for compound diaphragm, aims at solving the above-mentioned problem that proposes.

Disclosure of Invention

Aiming at the defects of the conventional receiving device of the die-cutting machine for the optical composite membrane in the prior art in the using process, the invention provides the receiving device of the die-cutting machine for the optical composite membrane, which has the advantage of receiving materials without stopping the machine and solves the problems in the prior art.

The invention provides the following technical scheme: the utility model provides a cross cutting machine receiving device for compound diaphragm of optics, includes the base, fixed mounting has the support frame on the position that the base top is close to one end, the axis of rotation has been cup jointed in the activity on the position that support frame one side is close to the top, fixed mounting has the connecting rod on the surface of axis of rotation is close to the position at both ends, the one end fixed mounting of connecting rod has the buckle, the inside joint of buckle has the live-rollers, the surface cover of live-rollers is equipped with and remains to cut the membrane, one side fixed mounting that the top of base is close to the support frame has the stroke device, fixed mounting has the processing desktop on the position that the top of base is located stroke device one side, the top fixed mounting of processing desktop has the cutting machine, fixed mounting has main drive roller on the position that processing desktop top is located cutting machine one side.

Preferably, the connecting rods are arranged on the outer surface of the rotating shaft in an annular array mode, and the number of the rotating rollers is two, and the rotating rollers are connected with the adjacent connecting rods in a clamping mode.

Preferably, the stroke device comprises a support, a fixed roller is movably sleeved at a position close to the middle of one side of the support, a telescopic machine is fixedly mounted at the top of the support, a limiting rotating seat is fixedly mounted at one end of an output shaft of the telescopic machine, a stroke roller is rotatably arranged between the limiting rotating seats, a connecting plate I is fixedly sleeved on the outer surface of the output shaft of the telescopic machine, an auxiliary driving roller is fixedly mounted at one side of the connecting plate I, an upper fixing plate and a lower fixing plate are fixedly mounted at a position close to the fixed roller at one side inside the support, laser transmitters are fixedly mounted at positions close to two sides of the bottom of the upper fixing plate and correspond to a film to be cut, a laser receiver is fixedly mounted at the top of the lower fixing plate and corresponds to the laser receiver, and an adhesive injection device is fixedly mounted at the front of the support, and a cutter is fixedly arranged on the back surface of the bracket and corresponds to the film to be cut.

Preferably, the output end of the laser receiver is connected with the input end of the telescopic machine in a signal connection mode.

Preferably, the injecting glue device includes connecting plate II, one side fixed mounting of connecting plate II has the mounting panel, the bottom fixed mounting of mounting panel has the injecting glue storehouse, the injecting glue mouth has been seted up on the position that injecting glue storehouse one side is close to the bottom, fixed mounting has the presser on the position that the mounting panel top is close to in both ends, the presser is linked together with the injecting glue storehouse, the top fixed mounting of connecting plate II has the controller.

Preferably, the output end of the laser receiver is connected with the input end of the controller in a signal connection mode.

Preferably, the membrane to be cut comprises a membrane plate, corresponding holes are formed in the positions, close to the head end and the tail end, of the two sides of the membrane plate, a cutting area is arranged at the top of the membrane plate, and the position of the cutting area corresponds to the corresponding holes.

Preferably, the laser transmitter corresponds to a cutting area.

The invention has the following beneficial effects:

1. the invention enables the laser transmitter to emit laser when the device operates by corresponding the laser transmitter and the laser receiver, the main driving roller is in a rotating state, and the film plate is only provided with corresponding holes at the positions close to the head end and the tail end, so that the laser transmitted by the laser transmitter can not pass through the film plate connected with the main driving roller, and the laser receiver can not receive the laser transmitted by the laser transmitter, when the film plate connected with the main driving roller is nearly used up, the film plate at the top of the film plate connected with the main driving roller close to the tail end can correspond to the laser transmitter, because the film plate connected with the auxiliary driving roller is kept in a static state, the laser can pass through the corresponding holes arranged at the tops of the two film plates, so that the laser is projected at the top of the laser receiver, and is connected with the input end of the auxiliary driving roller by a signal connection mode through the output end of the laser receiver, so that the auxiliary driving roller and the main driving roller keep synchronous rotation, the membrane plate connected with the main driving roller and the membrane to be cut connected with the auxiliary driving roller rotate synchronously, at the moment, a glue injection device is fixedly installed on the front side of the support, a cutter is fixedly installed on the back side of the support and corresponds to the membrane to be cut, the membrane to be cut is respectively connected with the auxiliary driving roller and the main driving roller, the output end of the laser receiver is connected with the input end of the controller in a signal connection mode, so that the controller controls the pressurizing machine to extrude the glue in the glue injection bin to be discharged from the glue injection port and fall on the top of the membrane plate connected with the main driving roller, at the moment, the output end of the laser receiver is connected with the input end of the expansion machine in a signal connection mode, the expansion machine drives the stroke roller to move in a vertical downward direction, the stroke roller is contacted with the fixed roller, at the moment, the membrane plate connected with the main driving roller is contacted with the membrane plate connected with the auxiliary driving roller, make two diaphragms be connected through glue, the mode that the output through laser receiver passes through signal connection at this moment is connected with the input of cutterbar, thereby make the cutterbar operation and will cut off with the diaphragm that vice drive roller is connected, thereby make the diaphragm that is cut off continue to move under the drive of main drive roller, and corresponding hole department in corresponding state behind two diaphragms adhesion mutually, thereby make the cutting area also keep corresponding state, the cutting area at diaphragm top after having guaranteed to accomplish to connect the material can keep corresponding with the lower sword position of cutting machine, thereby realize the automatic function of connecing the material, and traditional equipment need shut down the manual work and connect the material operation, lead to the inconvenient problem of complicated operation of operation, the automation of the device has been improved.

2. According to the invention, the connecting rods are arranged on the outer surface of the rotating shaft in an annular array mode, the number of the rotating rollers is two, and the rotating rollers are connected with the adjacent connecting rods in a clamping mode, so that the device can still clamp the rotating rollers sleeved with the film to be cut inside the buckles in the normal operation process, the stroke roller is controlled to move in the vertical upward direction through the telescopic machine, the film to be cut penetrates through the bottom of the stroke roller and is sleeved on the outer surface of the auxiliary driving roller, and the laser receiver is ensured to correspond to the corresponding hole in the top of the film plate, so that the rotating rollers and the film to be cut are replaced and installed without stopping, and the practicability of the device is improved.

Drawings

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

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

FIG. 3 is a schematic structural diagram of the main body of the present invention;

FIG. 4 is a schematic view of the structural stroke device of the present invention;

FIG. 5 is a schematic right-view of the structural stroke device of the present invention;

FIG. 6 is a schematic cross-sectional view taken along the direction A in FIG. 5 according to the present invention;

FIG. 7 is a schematic cross-sectional view taken along the direction B in FIG. 6 according to the present invention;

FIG. 8 is a schematic view of a glue injection apparatus according to the present invention;

FIG. 9 is a front view of the glue injection apparatus according to the present invention;

FIG. 10 is a schematic cross-sectional view taken along the direction C in FIG. 9;

FIG. 11 is a schematic diagram of a film to be cut according to the present invention.

In the figure: 1. a base; 2. a support frame; 3. a rotating shaft; 4. a connecting rod; 5. buckling; 6. a rotating roller; 7. cutting the film; 71. a diaphragm plate; 72. a corresponding hole; 73. cutting the area; 8. a stroke device; 81. a support; 82. a fixed roller; 83. a compressor; 84. a limiting rotating seat; 85. a stroke roller; 86. a connecting plate I; 87. a sub-driving roller; 88. an upper fixing plate; 89. a lower fixing plate; 801. a laser transmitter; 802. a laser receiver; 803. a glue injection device; 8031. a connecting plate II; 8032. mounting a plate; 8033. injecting a glue bin; 8034. a glue injection port; 8035. a press; 8036. a controller; 804. a cutter; 9. processing a desktop; 10. a cutting machine; 11. a main drive roller.

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.

Please refer to fig. 1-3, a receiving device of a die-cutting machine for an optical composite membrane comprises a base 1, a support frame 2 is fixedly mounted at a position close to one end of the top of the base 1, a rotating shaft 3 is movably sleeved at a position close to the top of one side of the support frame 2, a connecting rod 4 is fixedly mounted at a position close to two ends of the outer surface of the rotating shaft 3, a buckle 5 is fixedly mounted at one end of the connecting rod 4, a rotating roller 6 is clamped inside the buckle 5, a membrane 7 to be cut is sleeved on the outer surface of the rotating roller 6, a stroke device 8 is fixedly mounted at one side of the top of the base 1 close to the support frame 2, a processing table top 9 is fixedly mounted at a position on one side of the stroke device 8 at the top of the base 1, a cutting machine 10 is fixedly mounted at the top of the processing table top 9, and a main driving roller 11 is fixedly mounted at a position on one side of the cutting machine 10 at the top of the processing table top 9.

Referring to fig. 4-7, the connecting rods 4 are mounted on the outer surface of the rotating shaft 3 in an annular array manner, the two rotating rollers 6 are clamped with the two buckles 5 connected with the adjacent connecting rods 4, so that in the normal operation process of the device, the rotating rollers 6 sleeved with the film 7 to be cut can still be clamped inside the buckles 5, the stroke rollers 85 are controlled by the telescopic machine 83 to move in the vertical upward direction, the film 7 to be cut passes through the bottom of the stroke rollers 85 and is sleeved on the outer surface of the auxiliary driving roller 87, and the laser receiver 802 is ensured to correspond to the corresponding holes 72 on the top of the film plate 71, so that the rotating rollers 6 and the film 7 to be cut can be replaced and mounted without stopping the machine, and the practicability of the device is improved.

Referring to fig. 1-10, the stroke device 8 includes a bracket 81, a fixed roller 82 is movably sleeved on a position near the middle of one side of the bracket 81, a telescopic machine 83 is fixedly installed on the top of the bracket 81, a limit rotating seat 84 is fixedly installed on one end of an output shaft of the telescopic machine 83, a stroke roller 85 is rotatably installed between the limit rotating seats 84, a connecting plate i 86 is fixedly sleeved on the outer surface of the output shaft of the telescopic machine 83, a sub-driving roller 87 is fixedly installed on one side of the connecting plate i 86, an upper fixing plate 88 and a lower fixing plate 89 are fixedly installed on a position near the fixed roller 82 on one side inside of the bracket 81, laser transmitters 801 are fixedly installed on positions near two sides of the bottom of the upper fixing plate 88, the laser transmitters 801 correspond to the film 7 to be cut, a laser receiver 802 is fixedly installed on the top of the lower fixing plate 89, the laser transmitters 801 correspond to the laser receiver 802, so that the laser transmitters 801 can emit laser when the device is operated, and the main driving roller 11 is in a rotating state, and the corresponding holes 72 are only opened on the positions of the film plate 71 near the head and tail ends, so that the laser emitted by the laser emitter 801 can not pass through the film plate 71 connected with the main driving roller 11, and thus the laser receiver 802 can not receive the laser emitted by the laser emitter 801, when the film plate 71 connected with the main driving roller 11 is nearly used up, the top of the film plate 71 connected with the main driving roller 11 near the tail end film plate 71 can correspond to the laser emitter 801, because the film plate 71 connected with the auxiliary driving roller 87 is kept in a static state, the laser can pass through the corresponding holes 72 opened on the top of the two film plates 71, and thus the laser is projected on the top of the laser receiver 802, and is connected with the input end of the auxiliary driving roller 87 through a signal connection mode through the output end of the laser receiver 802, the auxiliary driving roller 87 and the main driving roller 11 are enabled to synchronously rotate, so that the film plate 71 connected with the main driving roller 11 and the film 7 to be cut connected with the auxiliary driving roller 87 synchronously rotate, at the moment, the glue injection device 803 is fixedly installed on the front surface of the bracket 81, the cutter 804 is fixedly installed on the back surface of the bracket 81, the cutter 804 corresponds to the film 7 to be cut, the film 7 to be cut is respectively connected with the auxiliary driving roller 87 and the main driving roller 11, the output end of the laser receiver 802 is connected with the input end of the controller 8036 in a signal connection mode, so that the controller 8036 controls the pressurizer 8035 to extrude glue in the glue injection cabin 8033 to be discharged from the glue injection port 8034 and fall on the top of the film plate 71 connected with the main driving roller 11, at the moment, the output end of the laser receiver 802 is connected with the input end of the expansion machine 83 in a signal connection mode, so that the expansion machine 83 drives the stroke roller 85 to move along a vertical downward direction, the stroke roller 85 is contacted with the fixed roller 82, the diaphragm 71 connected with the main driving roller 11 is contacted with the diaphragm 71 connected with the auxiliary driving roller 87, the two diaphragms 71 are connected through glue, the output end of the laser receiver 802 is connected with the input end of the cutter 804 through signal connection, so that the cutter 804 operates and separates the diaphragm 71 connected with the auxiliary driving roller 87, the cut diaphragm 71 is driven by the main driving roller 11 to move continuously, the corresponding holes 72 are in corresponding states after the two diaphragms 71 are adhered, the cutting area 73 is also kept in corresponding states, the cutting area 73 at the top of the diaphragm 71 after material receiving is ensured to be corresponding to the lower knife position of the cutting machine 10, the automatic material receiving function is realized, and the traditional equipment needs to be shut down and manually perform material receiving operation, resulting in complicated operation and inconvenient operation, and improving the automation of the device.

Referring to fig. 4-10, the output end of the laser receiver 802 is connected to the input end of the telescopic mechanism 83 by signal connection, and the output end of the laser receiver 802 is connected to the input end of the sub-driving roller 87 by signal connection.

Referring to fig. 8-10, the glue injection device 803 includes a connecting plate ii 8031, a mounting plate 8032 is fixedly mounted on one side of the connecting plate ii 8031, a glue injection bin 8033 is fixedly mounted at the bottom of the mounting plate 8032, a glue injection port 8034 is formed in a position close to the bottom of one side of the glue injection bin 8033, a presser 8035 is fixedly mounted in a position close to the top of the mounting plate 8032 in the two ends, the presser 8035 is communicated with the glue injection bin 8033, and a controller 8036 is fixedly mounted on the top of the connecting plate ii 8031.

Referring to fig. 4-10, the output of the laser receiver 802 is connected to the input of the controller 8036 by signal connection.

Referring to fig. 11, the film 7 to be cut includes a film plate 71, corresponding holes 72 are formed at positions on two sides of the film plate 71 near the head and the tail ends, a cutting area 73 is formed at the top of the film plate 71, and the position of the cutting area 73 corresponds to the corresponding hole 72.

Referring to fig. 4-7 and 11, a laser transmitter 801 corresponds to the cutting area 73.

The using method of the invention is as follows:

in the using process, the laser transmitter 801 emits laser, the main driving roller 11 is in a rotating state, and only the positions of the film plates 71 near the head and the tail ends are provided with corresponding holes 72, so that the laser emitted by the laser transmitter 801 cannot pass through the film plates 71 connected with the main driving roller 11, and the laser receiver 802 cannot receive the laser emitted by the laser transmitter 801, when the film plates 71 connected with the main driving roller 11 are nearly used up, the top of the film plate 71 connected with the main driving roller 11 near the tail end film plate 71 corresponds to the laser transmitter 801, because the film plates 71 connected with the auxiliary driving roller 87 are kept in a static state, the laser can pass through the corresponding holes 72 formed in the top of the two film plates 71, so that the laser is projected on the top of the laser receiver 802, and the laser receiver 802 receives the light emitted by the laser transmitter 801, thereby controlling the secondary driving roller 87 to start running, so that the secondary driving roller 87 and the primary driving roller 11 keep synchronous rotation, thereby enabling the film plate 71 connected with the primary driving roller 11 and the film 7 to be cut connected with the secondary driving roller 87 to rotate synchronously, the laser receiver 802 receives the light emitted by the laser emitter 801, thereby controlling the controller 8036 to start running, so that the controller 8036 controls the pressurizer 8035 to extrude the glue in the glue injecting bin 8033 to be discharged from the glue injecting port 8034 and fall on the top of the film plate 71 connected with the primary driving roller 11, the laser receiver 802 receives the light emitted by the laser emitter 801, thereby controlling the expander 83 to start running, so that the expander 83 drives the stroke roller 85 to move in a vertical downward direction, so that the stroke roller 85 is in contact with the fixed roller 82, and at the moment, the film plate 71 connected with the primary driving roller 11 is in contact with the film plate 71 connected with the secondary driving roller 87, the two film plates 71 are connected through glue, the cutter 804 operates and separates the film plates 71 connected with the auxiliary driving roller 87, so that the cut film plates 71 continuously move under the driving of the main driving roller 11, and the corresponding holes 72 are in a corresponding state after the two film plates 71 are adhered, so that the cutting area 73 is kept in a corresponding state.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a compound diaphragm of optics is with cross cutting machine receiving device, includes base (1), its characterized in that: one end of the upper part of the base (1) is oppositely provided with a support frame (2), a rotating shaft (3) is sleeved between the support frames (2), a plurality of connecting rods (4) are circumferentially arranged at both ends of the rotating shaft (3), buckles (5) are fixedly arranged at the end parts of the connecting rods (4), a rotating roller (6) is clamped in the buckle (5), a film (7) to be cut is sleeved on the outer surface of the rotating roller (6), a stroke device (8) is fixedly arranged on one side of the top of the base (1) close to the support frame (2), a processing desktop (9) is fixedly arranged at the top of the base (1) and positioned at one side of the stroke device (8), the top fixed mounting of processing desktop (9) has cutting machine (10), processing desktop (9) top is located and is rotated on the position of cutting machine (10) one side and be connected with main drive roller (11).

2. The receiving device of the die-cutting machine for the optical composite membrane, according to claim 1, is characterized in that: the outer surface at axis of rotation (3) is installed with annular array's mode in connecting rod (4), the quantity of live-rollers (6) is two and with adjacent buckle (5) joint.

3. The receiving device of the die-cutting machine for the optical composite membrane, according to claim 1, is characterized in that: the stroke device (8) comprises a support (81), a fixed roller (82) is arranged on a position, close to the middle, of one side of the support (81) in a rotating mode, a telescopic machine (83) is fixedly installed at the top of the support (81), a limiting rotating seat (84) is fixedly installed at one end of an output shaft of the telescopic machine (83), a stroke roller (85) is arranged between the limiting rotating seat (84) in a rotating mode, a connecting plate I (86) is sleeved on the outer surface of the output shaft of the telescopic machine (83), an auxiliary driving roller (87) is fixedly installed on one side of the connecting plate I (86), an upper fixing plate (88) and a lower fixing plate (89) are fixedly installed on a position, close to the two sides, of the bottom of the upper fixing plate (88) in a fixing mode, a laser transmitter (801) corresponds to a film to be cut (7), the top fixed mounting of bottom plate (89) has laser receiver (802), laser emitter (801) and laser receiver (802) are corresponding, the front fixed mounting of support (81) has injecting glue device (803), the back fixed mounting of support (81) has cutterbar (804), cutterbar (804) and waiting to cut membrane (7) are corresponding, the output of laser receiver (802) is connected with the input of cutterbar (804) through signal connection's mode.

4. The receiving device of the die-cutting machine for the optical composite membrane, according to claim 3, is characterized in that: the output end of the laser receiver (802) is connected with the input end of the telescopic machine (83) in a signal connection mode.

5. The receiving device of the die-cutting machine for the optical composite membrane, according to claim 3, is characterized in that: injecting glue device (803) are including connecting plate II (8031), one side fixed mounting of connecting plate II (8031) has mounting panel (8032), the bottom fixed mounting of mounting panel (8032) has injecting glue storehouse (8033), injecting glue has been seted up on storehouse (8033) one side is close to the position of bottom and has been annotated injecting glue mouth (8034), fixed mounting has presser (8035) on the position that mounting panel (8032) top is close to both ends in, presser (8035) are linked together with injecting glue storehouse (8033), the top fixed mounting of connecting plate II (8031) has controller (8036).

6. The receiving device of the die-cutting machine for the optical composite membrane, according to claim 5, is characterized in that: the output end of the laser receiver (802) is connected with the input end of the controller (8036) in a signal connection mode.

7. The receiving device of the die-cutting machine for the optical composite membrane, according to claim 3, is characterized in that: the film (7) to be cut comprises a film plate (71), corresponding holes (72) are formed in the positions, close to the head end and the tail end, of the two sides of the film plate (71), a cutting area (73) is arranged at the top of the film plate (71), and the position of the cutting area (73) corresponds to the corresponding holes (72).

8. The receiving device of the die-cutting machine for the optical composite membrane, according to claim 7, is characterized in that: the laser transmitter (801) corresponds to a cutting area (73).

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