CN218114401U - Feeding device of die-cutting machine - Google Patents

Abstract

The utility model discloses a material feeding unit of cross cutting machine, include: the device comprises a bracket, a first feeding mechanism and a turnover driving device; the first feeding mechanism comprises a first driving device and a first material taking part; the first material taking component is used for grabbing or releasing materials; the first driving device is used for driving the first material taking part to switch between the inlet of the die cutting machine and the first station; one end of the first feeding mechanism is hinged with the bracket to form a hinge part; the overturning driving device is used for driving the first feeding mechanism to rotate around the hinge part, so that the first feeding mechanism is switched to a horizontal state or an inclined state; when the first feeding mechanism is in a horizontal state, the first material taking piece grabs the material on the first station; when the first feeding mechanism is in an inclined state, the first material taking part is driven to the inlet of the die cutting machine, and the first material taking part releases materials, so that the materials fall into the inlet of the die cutting machine. The utility model discloses can send the material to cross cutting machine entrance automatically, reduce workman's operating strength, improve production efficiency and reduce the operation risk.

Description

Feeding device of die-cutting machine

Technical Field

The utility model relates to a cross cutting machine technical field especially relates to a material feeding unit of cross cutting machine.

Background

The die cutting machine is a common machine in industrial production, is mainly used for cutting some non-metal materials such as paperboards and the like, utilizes a steel knife or a die to roll and cut the materials into certain shapes by applying certain pressure, and is important equipment in the packaging industry. In the existing die cutting machine, a paperboard material is generally manually placed in an inlet of the die cutting machine, and the paperboard enters the die cutting machine from the inlet of the die cutting machine to be rolled and cut. This kind of mode of manually placing the cardboard is big to workman's operation intensity, and production efficiency is low, and has certain safety risk, takes place the incident easily.

SUMMERY OF THE UTILITY MODEL

In order to overcome prior art not enough, the utility model provides a material feeding unit of cross cutting machine can send the material to cross cutting machine entrance automatically, reduces workman's operating strength, improves production efficiency and reduces the operation risk.

The utility model discloses the first aspect provides a material feeding unit of cross cutting machine, include:

the device comprises a bracket, a first feeding mechanism and a turnover driving device; the first feeding mechanism comprises a first driving device and a first material taking part; the first material taking piece is used for grabbing or releasing materials; the first driving device is used for driving the first material taking part to switch between an inlet of the die cutting machine and a first station; one end of the first feeding mechanism is hinged with the bracket to form a hinged part; the overturning driving device is used for driving the first feeding mechanism to rotate around the hinged part, so that the first feeding mechanism is switched to a horizontal state or an inclined state;

when the first feeding mechanism is in a horizontal state, the first material taking piece grabs the material on the first station; when the first feeding mechanism is in an inclined state, the first material taking part is driven to the inlet of the die cutting machine from the first station, and the first material taking part releases materials, so that the materials fall into the inlet of the die cutting machine.

In the first aspect of the present invention, as a preferred embodiment, the turnover driving means includes a turnover part and a second driving means; one end of the turning part is connected with the second driving device, and the other end of the turning part is abutted to the lower end of the first feeding mechanism, so that the turning part is driven by the second driving device to turn over for a preset angle, and the first feeding mechanism is driven to be switched between a horizontal state and an inclined state.

In the first aspect of the present invention, as a preferred embodiment, the turning part includes a rolling wheel, a bending rod, and a rotating pin; the fixed end of the second driving device is arranged on the bracket, and the movable end of the second driving device is hinged with the lower end of the bending rod; the middle part of the bending rod is provided with a connecting hole; one end of the rotating pin shaft penetrates through the connecting hole to be hinged with the bending rod, so that the bending rod can rotate around the rotating pin shaft; the other end of the rotating pin shaft is fixedly arranged on the bracket; the middle of the rolling wheel is provided with a mounting hole; the rolling wheel is arranged at the upper end of the bent rod in a rolling way through the mounting hole; the circumferential surface of the rolling wheel is abutted against the lower end of the first feeding mechanism.

In the first aspect of the present invention, as a preferred embodiment, the second driving device is a cylinder; the bending bar comprises a first force arm and a second force arm which are at an angle of 90 degrees with each other; one end of the first force arm is fixedly connected with one end of the second force arm; the other end of the first force arm is connected with the rolling wheel; the fixed end of the air cylinder is arranged on the bracket, and the movable end of the air cylinder is hinged with the second force arm through a movable connecting piece; when the movable end of the air cylinder extends out, the second force arm is driven to rotate, so that the first force arm is driven to rotate to a preset angle, and the first feeding mechanism abutted against the rolling wheel is turned over from an inclined state to a horizontal state; when the movable end of the air cylinder retracts, the air cylinder drives the first force arm and the second force arm to reset, and the first feeding mechanism is switched back to an inclined state from a horizontal state.

In the first aspect of the present invention, as an preferred embodiment, the first material taking member includes:

a first grasping mechanism; the first grabbing mechanism comprises a first grabbing plate and a plurality of suckers; the sucker is arranged on the first grabbing plate;

the first lifting mechanism is fixedly arranged on the first driving device; the first grabbing mechanism is arranged on the first lifting mechanism;

the first lifting driving device is connected with the first lifting mechanism; the first lifting driving device drives the first lifting mechanism to move up and down, so that the first grabbing mechanism is driven to move up and down.

In the first aspect of the present invention, as a preferred embodiment, the first driving device includes a fixed bracket; the fixed bracket comprises two groups of slide rail fixed seats which are oppositely arranged; the sliding rail fixing seats are respectively provided with a first sliding rail; the first slide rails are respectively provided with a first slide block; the first sliding blocks are fixedly connected with each other through the first sliding seats; the first lifting mechanism is fixedly arranged in the middle of the first sliding seat; two groups of synchronous wheels are respectively arranged at two ends of the fixed bracket; wherein, the two groups of synchronizing wheels far away from the die cutting machine are fixedly connected through a synchronizing shaft; one end of the synchronous shaft is also connected with a first driving motor; two groups of synchronous wheels arranged on the same fixed bracket are connected with synchronous belts in a winding way; the synchronous belt is fixedly connected with the first sliding block; the first driving motor drives the synchronizing shaft to rotate, the synchronizing shaft drives the synchronizing wheel to drive the synchronizing belt to move, so that the first sliding seat is driven to do linear motion along the first sliding rail, and the first lifting mechanism arranged on the first sliding seat drives the first grabbing mechanism to switch between the inlet of the die-cutting machine and the first station; when the first grabbing mechanism moves to the inlet of the die cutting machine from the first station, the first material taking part moves to one end close to the die cutting machine from one end far away from the die cutting machine along the first sliding rail.

In the first aspect of the present invention, as a preferred embodiment, the feeding device of the die cutting machine further includes a second feeding mechanism; the second feeding mechanism comprises a material pushing block and a third driving device; the material pushing block is arranged on the third driving device; when the third driving device drives the material pushing block to move from one end far away from the die cutting machine to one end close to the die cutting machine, the material pushing block pushes the material from the second station to the first station.

In the first aspect of the present invention, as a preferred embodiment, the feeding device of the die cutting machine further includes a raw material placing plate for stacking materials; the raw material placing plate is fixedly arranged on the bracket; the material is in the third station when it is on the stock placing plate.

In the first aspect of the present invention, as a preferred embodiment, the feeding device of the die cutting machine further includes a third feeding mechanism for transferring the material from the third station to the second station; the third feeding mechanism is arranged on the bracket; the third feeding mechanism comprises a fourth driving device and a second material taking part; the second material taking piece is arranged on the fourth driving device; the second material taking component is used for grabbing or releasing materials; and the fourth driving device drives the second material taking part to switch between a third station and a second station.

In the first aspect of the present invention, as a preferred embodiment, the support further includes a protection plate and a roller; the protection plates are arranged around the support; the roller is arranged at the bottom of the bracket.

Compared with the prior art, the beneficial effects of the utility model reside in that:

the feeding device of the die-cutting machine is provided with a first feeding mechanism on a bracket, and the first feeding mechanism comprises a first driving device and a first material taking part; the first driving device is used for driving the first material taking part to switch between the inlet of the die cutting machine and the first station; one end of the first feeding mechanism is hinged with the bracket to form a hinged part; the overturning driving device is used for driving the first feeding mechanism to rotate around the hinge part, so that the first feeding mechanism is switched to a horizontal state or an inclined state; when the first feeding mechanism is in a horizontal state, the first material taking piece grabs the material on the first station; when the first feeding mechanism is in an inclined state, the first material taking part is driven to the inlet of the die cutting machine from the first station, and the first material taking part releases materials, so that the materials fall into the inlet of the die cutting machine. The utility model discloses can send the material to cross cutting machine entrance automatically, reduce workman's manipulation strength, improve production efficiency and reduce the operation risk.

Drawings

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

fig. 2 is a schematic structural view of another aspect of the present invention;

fig. 3 is a schematic structural view of the first material taking member of the present invention;

fig. 4 is a schematic structural view of the turnover driving device of the present invention;

fig. 5 is a schematic structural diagram of the first driving device of the present invention;

fig. 6 is a schematic structural view of the third feeding mechanism of the present invention.

In the figure: 1. a support; 10. a discharging platform; 2. a first feeding mechanism; 21. a first driving device; 211. a slide rail fixing seat; 212. a first slide rail; 213. a first slider; 214. a first sliding seat; 215. a synchronizing wheel; 216. a synchronizing shaft; 217. a synchronous belt; 22. a first material taking part; 221. a first grasping mechanism; 2211. a first grasping plate; 2212. a suction cup; 222. a first lifting mechanism; 223. a first elevation drive device; 3. a turnover driving device; 31. a turning part; 311. a rolling wheel; 312. a curved rod; 313. rotating the pin shaft; 32. a second driving device; 4. die-cutting machine; 5. a second feeding mechanism; 51. a material pushing block; 52. a third driving device; 6. a raw material placing plate; 7. a third feeding mechanism; 71. a fourth drive device; 72. a second material taking part; 81. a protection plate; 82. a roller; 9. a material.

Detailed Description

The following description of the present invention will be made with reference to the accompanying drawings and the detailed description thereof, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict. Except as specifically noted, the materials and equipment used in this example are commercially available. Examples of embodiments are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary only for explaining the present application and are not to be construed as limiting the present application.

In the description of the present application, it is to be understood that the terms "upper", "lower", "front", "back", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present application. In the description of the present application, "a plurality" means two or more unless specifically stated otherwise.

In the description of the present application, it should be noted that unless otherwise specifically stated or limited, the terms "connected," "communicating," and "connected" are to be construed broadly, e.g., as meaning a fixed connection, a connection through an intervening medium, a connection between two elements, or an interaction between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

The terms "first," "second," and the like in the description and in the claims of the present application and in the above-described drawings are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Example one

The feeding device of the die-cutting machine 4 shown in figures 1-6 comprises a bracket 1, a first feeding mechanism 2 and a turnover driving device 3; the first feeding mechanism 2 comprises a first driving device 21 and a first material taking part 22; the first material taking part 22 is used for grabbing or releasing the material 9; the first driving device 21 is used for driving the first material taking part 22 to switch between the inlet of the die cutting machine and the first station; one end of the first feeding mechanism 2 is hinged with the bracket 1 to form a hinge part; the overturning driving device 3 is used for driving the first feeding mechanism 2 to rotate around the hinge part, so that the first feeding mechanism 2 is switched to a horizontal state and an inclined state;

when the first feeding mechanism 2 is in a horizontal state, the first material taking part 22 grabs the material 9 at the first station, the support 1 is provided with the material placing platform 10, the material 9 is placed at a designated position on the material placing platform 10, the material 9 is in a horizontal state, and when the first feeding mechanism 2 is in a horizontal state, the first lifting mechanism 222 can realize that the first grabbing plate 2211 grabs the material 9 through the suction disc 2212 through lifting action; when the first feeding mechanism 2 is in an inclined state, the first feeding mechanism 2 is parallel to an inlet of the die cutting machine at the inlet of the die cutting machine, the first material taking part 22 is communicated with the adsorbed material 9 and moves to the inlet of the die cutting machine from the first station, and the material 9 is released at the inlet of the die cutting machine 4, so that the material 9 falls into the inlet of the die cutting machine, and automatic feeding is realized. It should be noted that the above horizontal state is not limited to the absolute horizontal state, and a certain deviation under objective conditions is allowed, and the angle that the material does not slip in this state can be considered as being within the protection scope defined by the present feature, and those skilled in the art can understand it.

Specifically, the placing platform 10 in this embodiment is installed on the support 1, and a positioning device is disposed on the placing platform 10, so that the material 9 can be fixedly placed at a designated position on the placing platform 10. The positioning device in the embodiment comprises two positioning plates which are oppositely arranged, the parts of the positioning plates extend out of the material placing platform 10, guide rods are arranged below the positioning plates, the positioning plates are connected with each other through a screw rod structure, and the screw rods are driven by a motor to enable the positioning plates to move towards each other or away from each other, so that the positioning device can be adjusted according to the specific size of the material 9.

As a preferred embodiment, the inversion drive device 3 includes an inversion section 31 and a second drive device 32; one end of the turning part 31 is connected with the second driving device 32, and the other end of the turning part is abutted to the lower end of the first feeding mechanism 2, so that the turning part 31 is turned over by a preset angle under the driving of the second driving device 32, and the first feeding mechanism 2 is driven to be switched between a horizontal state and an inclined state.

As a preferred embodiment, the turning part 31 includes a rolling wheel 311, a bending rod 312, and a rotating pin 313; the fixed end of the second driving device 32 is mounted on the bracket 1, and the movable end thereof is hinged with the lower end of the bending rod 312; the middle part of the bent rod 312 is provided with a connecting hole; one end of the rotating pin shaft 313 penetrates through the connecting hole to be hinged with the bending rod 312, so that the bending rod 312 can rotate around the rotating pin shaft 313; the other end of the rotating pin shaft 313 is fixedly arranged on the bracket 1; the middle of the rolling wheel 311 is provided with a mounting hole; the rolling wheel 311 is rollably mounted on the upper end of the curved rod 312 through the mounting hole; the circumferential surface of the roller wheel 311 abuts against the lower end of the first feeding mechanism 2.

In a preferred embodiment, the second driving device 32 is a cylinder; the bending bar 312 includes a first moment arm and a second moment arm at a 90 ° angle to each other; one end of the first force arm is fixedly connected with one end of the second force arm; the other end of the first force arm is connected with the rolling wheel 311; the fixed end of the cylinder is arranged on the bracket 1, and the movable end of the cylinder is hinged with the second force arm through a movable connecting piece; the movable end of the cylinder is a piston rod; specifically, when the piston rod of the air cylinder extends, the bending rod 312 rotates around the rotating pin 313, and the rolling wheel 311 abuts against the lower end of the first feeding mechanism 2, so that the first feeding mechanism 2 is jacked up from the lower side by the rolling wheel 311, and when the piston rod extends completely, the first feeding mechanism 2 is in a horizontal state, so that the first material taking part 22 can conveniently grab the material 9 on the first station; when the cylinder piston rod retracts, the bending rod 312 is driven to return to the original state, and the first feeding mechanism 2 falls to the original inclined position, so that the first material taking part 22 with the material 9 is conveyed from the first station to the inlet of the die cutting machine at the inlet of the die cutting machine. It should be noted that in this embodiment, there are two sets of the turnover driving devices 3 respectively disposed on two sides of the bracket 1, and two sides of the first feeding mechanism 2 are both abutted against the rollers 82 of the turnover part 31, so that the two sides of the first feeding mechanism 2 are synchronized.

As a preferred embodiment, the first picking member 22 includes:

a first grasping mechanism 221; the first grabbing mechanism 221 includes a first grabbing plate 2211 and a plurality of suckers 2212; the suction cup 2212 is mounted on the first grip plate 2211;

a first lifting mechanism 222, wherein the first lifting mechanism 222 is fixedly arranged on the first driving device 21; the first gripping mechanism 221 is mounted on the first lifting mechanism 222;

a first elevation driving device 223, wherein the first elevation driving device 223 is connected with the first elevation mechanism 222; the first lifting driving device 223 drives the first lifting mechanism 222 to move up and down, so as to drive the first grabbing mechanism 221 to move up and down.

As a preferred embodiment, the first driving means 21 comprise a fixed support 1; the fixed bracket 1 comprises two groups of slide rail fixed seats 211 which are oppositely arranged; the slide rail fixing seats 211 are respectively provided with a first slide rail 212; the first slide rails 212 are respectively provided with a first slide block 213; the first sliders 213 are fixedly connected to each other by a first sliding seat 214; the first lifting mechanism 222 is fixedly installed in the middle of the first sliding seat 214; two groups of synchronous wheels 215 are respectively arranged at two ends of the fixed bracket 1; two groups of synchronizing wheels 215 far away from the die cutting machine 4 are fixedly connected through a synchronizing shaft 216; one end of the synchronous shaft 216 is also connected with a first driving motor; two groups of synchronous wheels 215 arranged on the same fixed bracket 1 are connected with a synchronous belt 217 in a winding way; the synchronous belt 217 is fixedly connected with the first sliding block 213; the first driving motor drives the synchronizing shaft 216 to rotate, the synchronizing shaft 216 drives the synchronizing wheel 215 to drive the synchronizing belt 217 to move, so as to drive the first sliding seat 214 to make linear motion along the first sliding rail 212, and the first lifting mechanism 222 mounted on the first sliding seat 214 drives the first grabbing mechanism 221 to switch between the inlet of the die cutting machine and the first station; when the first grasping mechanism 221 moves from the first station to the entrance of the die cutting machine, the first take-out member 22 moves along the first slide rail 212 from the end away from the die cutting machine 4 to the end near the die cutting machine 4.

As a preferred embodiment, the feeding device of the die-cutting machine 4 further comprises a second feeding mechanism 5; the second feeding mechanism 5 is arranged below the discharging platform 10; the second feeding mechanism 5 comprises a material pushing block 51 and a third driving device 52, wherein the material pushing block partially extends out of the upper part of the emptying platform 10; the material pushing block 51 is arranged on the third driving device 52; when the third driving device 52 drives the material pushing block 51 to move from the end far away from the die cutting machine 4 to the end close to the die cutting machine 4, the material pushing block 51 pushes the material 9 from the second station to the first station. Because the material placing platform 10 is also provided with the positioning device, the positioning device limits that the material 9 can only move back and forth along the linear direction from the second station to the first station, and the material pushing block 51 is arranged below the material placing platform 10, so that the space is reasonably utilized, the overall structure size of the material feeding device is favorably reduced, and the space is saved.

As a preferred embodiment, the feeding device of the die-cutting machine 4 also comprises a raw material placing plate 6 for stacking the material 9; the raw material placing plate 6 is fixedly arranged on the bracket 1; when the material 9 is on the material-placing plate 6, the material 9 is in the third station. The material 9 may be manually placed on the raw material placing plate 6, or may be automatically placed on the raw material placing plate 6 by a production line mechanism linked at a higher stage. In addition, the raw material placing platform is also provided with an automatic lifting mechanism, and automatic lifting can be realized according to the thickness of the stacked materials 9, so that the plane of the materials 9 is always kept at the same height, and the materials 9 can be grabbed.

As a preferred embodiment, the feeding device of the die-cutting machine 4 further comprises a third feeding mechanism 7 for transferring the material 9 from the third station to the second station; the third feeding mechanism 7 is arranged on the bracket 1; the third feeding mechanism 7 comprises a fourth driving device 71 and a second material taking part 72; the second material taking part 72 is arranged on the fourth driving device 71; the second material taking part 72 is used for grabbing or releasing the material 9; the fourth driving device 71 drives the second material taking member 72 to switch between the third station and the second station.

As a preferred embodiment, the stand 1 further comprises a shielding plate 81 and a roller 82; the protection plate 81 is arranged around the bracket 1, and the protection plate 81 can protect various driving mechanisms in the feeding device, so that the mechanism damage caused by the entry of foreign matters is avoided, and the occurrence of safety accidents is reduced; the rollers 82 are mounted on the bottom of the frame 1 to facilitate movement and adjustment of the position of the feeding device.

The feeding device of the die-cutting machine is provided with a first feeding mechanism 2 on a bracket 1, and the first feeding mechanism 2 comprises a first driving device 21 and a first material taking part 22; the first driving device 21 is used for driving the first material taking part 22 to switch between the inlet of the die cutting machine and the first station; one end of the first feeding mechanism is hinged with the bracket 1 to form a hinge part; the turnover driving device 3 is used for driving the first feeding mechanism 2 to rotate around the hinge portion, so that the first feeding mechanism 2 is switched to a horizontal state or an inclined state. When the first feeding mechanism 2 is in a horizontal state, the first material taking part 22 grabs the material 9 on the first station, then the first feeding mechanism 2 is switched to an inclined state, the first material taking part 22 is driven to the inlet of the die cutting machine from the first station, and the first material taking part 22 releases the material 9, so that the material 9 falls into the inlet of the die cutting machine. The utility model discloses can send the material to cross cutting machine entrance automatically, reduce workman's manipulation strength, improve production efficiency and reduce the operation risk.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims (10)

1. The utility model provides a material feeding unit of cross cutting machine which characterized in that includes: the device comprises a bracket, a first feeding mechanism and a turnover driving device; the first feeding mechanism comprises a first driving device and a first material taking part; the first material taking member is used for grabbing or releasing materials; the first driving device is used for driving the first material taking part to switch between an inlet of the die cutting machine and a first station; one end of the first feeding mechanism is hinged with the bracket to form a hinged part; the overturning driving device is used for driving the first feeding mechanism to rotate around the hinged part, so that the first feeding mechanism is switched to a horizontal state or an inclined state;

when the first feeding mechanism is in a horizontal state, the first material taking piece grabs the material on the first station; when the first feeding mechanism is in an inclined state, the first material taking part is driven to the inlet of the die cutting machine from the first station, and the first material taking part releases materials, so that the materials fall into the inlet of the die cutting machine.

2. The feeding device of a die cutting machine according to claim 1, characterized in that: the overturning driving device comprises an overturning part and a second driving device; one end of the turning part is connected with the second driving device, and the other end of the turning part is abutted to the lower end of the first feeding mechanism, so that the turning part is driven by the second driving device to turn over for a preset angle, and the first feeding mechanism is driven to switch between a horizontal state and an inclined state.

3. The feeding device of a die cutting machine according to claim 2, characterized in that: the overturning part comprises a rolling wheel, a bending rod and a rotating pin shaft; the fixed end of the second driving device is arranged on the bracket, and the movable end of the second driving device is hinged with the lower end of the bending rod; the middle part of the bending rod is provided with a connecting hole; one end of the rotating pin shaft penetrates through the connecting hole to be hinged with the bending rod, so that the bending rod can rotate around the rotating pin shaft; the other end of the rotating pin shaft is fixedly arranged on the bracket; the middle of the rolling wheel is provided with a mounting hole; the rolling wheel is arranged at the upper end of the bent rod in a rolling way through the mounting hole; the circumferential surface of the rolling wheel is abutted against the lower end of the first feeding mechanism.

4. The feeding device of a die cutting machine as set forth in claim 3, characterized in that: the second driving device is an air cylinder; the bending rod comprises a first force arm and a second force arm which form an angle of 90 degrees with each other; one end of the first force arm is fixedly connected with one end of the second force arm; the other end of the first force arm is connected with the rolling wheel; the fixed end of the air cylinder is arranged on the bracket, and the movable end of the air cylinder is hinged with the second force arm through a movable connecting piece; when the movable end of the cylinder extends out, the second force arm is driven to rotate, so that the first force arm is driven to rotate to a preset angle, and the first feeding mechanism abutted with the rolling wheel is enabled to turn over from an inclined state to a horizontal state; when the movable end of the air cylinder retracts, the air cylinder drives the first force arm and the second force arm to reset, and the first feeding mechanism is switched to an inclined state from a horizontal state.

5. The feeding device of a die cutting machine according to claim 1, characterized in that: the first take out member includes:

a first grasping mechanism; the first grabbing mechanism comprises a first grabbing plate and a plurality of suckers; the sucker is arranged on the first grabbing plate;

the first lifting mechanism is fixedly arranged on the first driving device; the first grabbing mechanism is arranged on the first lifting mechanism;

the first lifting driving device is connected with the first lifting mechanism; the first lifting driving device drives the first lifting mechanism to move up and down, so that the first grabbing mechanism is driven to move up and down.

6. The feeding device of a die cutting machine as set forth in claim 5, characterized in that: the first driving device comprises a fixed bracket; the fixed bracket comprises two groups of slide rail fixed seats which are oppositely arranged; the sliding rail fixing seats are respectively provided with a first sliding rail; the first slide rails are respectively provided with a first slide block; the first sliding blocks are fixedly connected with each other through the first sliding seats; the first lifting mechanism is fixedly arranged in the middle of the first sliding seat; two groups of synchronous wheels are respectively arranged at two ends of the fixed bracket; wherein, the two groups of synchronizing wheels far away from the die cutting machine are fixedly connected through a synchronizing shaft; one end of the synchronous shaft is also connected with a first driving motor; two groups of synchronous wheels arranged on the same fixed bracket are connected with synchronous belts in a winding way; the synchronous belt is fixedly connected with the first sliding block; the first driving motor drives the synchronizing shaft to rotate, the synchronizing shaft drives the synchronizing wheel to drive the synchronizing belt to move, so that the first sliding seat is driven to do linear motion along the first sliding rail, and the first lifting mechanism arranged on the first sliding seat drives the first grabbing mechanism to switch between the inlet of the die-cutting machine and the first station; when the first grabbing mechanism moves to an inlet of the die cutting machine from the first station, the first material taking part moves to one end close to the die cutting machine from one end far away from the die cutting machine along the first sliding rail.

7. The feeding device of a die cutting machine according to claim 1, characterized in that: the device also comprises a second feeding mechanism; the second feeding mechanism comprises a material pushing block and a third driving device; the material pushing block is arranged on the third driving device; when the third driving device drives the material pushing block to move from one end far away from the die cutting machine to one end close to the die cutting machine, the material pushing block pushes the material from the second station to the first station.

8. The feeding device of a die cutting machine as recited in claim 7, wherein: also comprises a raw material placing plate for stacking materials; the raw material placing plate is fixedly arranged on the bracket; the material is in the third station when it is on the stock placing plate.

9. The feeding device of a die cutting machine as recited in claim 8, wherein: the third feeding mechanism is used for conveying the materials from the third station to the second station; the third feeding mechanism is arranged on the bracket; the third feeding mechanism comprises a fourth driving device and a second material taking part; the second material taking piece is arranged on the fourth driving device; the second material taking piece is used for grabbing or releasing materials; and the fourth driving device drives the second material taking part to switch between a third station and a second station.

10. The feeding device of a die cutting machine according to claim 1, characterized in that: the support also comprises a protection plate and a roller; the protection plates are arranged on the periphery of the support; the roller is arranged at the bottom of the bracket.

Images