CN114985843B - Aluminum template cutting device - Google Patents

Abstract

The invention discloses an aluminum template cutting device, which relates to the technical field of aluminum template processing equipment and comprises a cutting device body, wherein the cutting device body is provided with an imprinting device and a material guide mechanism, and the material guide mechanism passes through the lower part of an output end of the imprinting device; the device also comprises a separating mechanism, a discharging mechanism and a recycling mechanism, wherein the recycling mechanism and the discharging mechanism are positioned at one side of the output end of the material guiding mechanism, the separating mechanism is positioned between the embossing device and the discharging mechanism, the separating mechanism is arranged below the material guiding mechanism, and the discharging mechanism is positioned above the separating mechanism; according to the invention, the ejector rod is driven to move along the surface of the inner shell by the rotating circulating belt, and when the ejector rod passes through the convex part, the embossed objects are ejected upwards and separated along the fluctuation, and meanwhile, the ejected embossed objects are transferred. Meanwhile, the residual leftover materials are pressed on the material guide mechanism, so that the die-cut materials are separated from the upper direction and the lower direction respectively, and the separation effect is better and the accuracy is higher.

Description

Aluminum template cutting device

Technical Field

The invention relates to the technical field of aluminum template processing equipment, in particular to an aluminum template cutting device.

Background

The aluminum alloy template is called as a concrete engineering aluminum alloy template, and is a new generation template system after a plywood template, a combined steel template system, a steel frame wood (bamboo) plywood system, a large template system and an early-dismantling template system. The aluminum alloy template takes aluminum alloy section bars as main materials, is a template which is suitable for concrete engineering and is manufactured through mechanical processing, welding and other processes, and is formed by combining a panel, ribs, a main body section bar, a plane template, a corner template and an early dismounting device according to a 50mm modulus design. The aluminum alloy template design and construction application are innovations in concrete engineering template technology, are pushing of assembly type concrete technology, and are industrialized expression of construction technology.

The aluminum alloy template system can be divided into a pull rod system and a pull sheet body system according to different stress modes. The aluminum alloy template of the pull rod system consists of a template system, a fastening system, a supporting system and an accessory system, has a complete matched template system, is suitable for different ranges of template system pull sheet body system aluminum alloy templates of urban pipe lanes, public buildings, residential buildings and the like, consists of three parts of template systems, supporting systems and accessory systems, has a complete matched template system, and is generally suitable for residential buildings.

A large amount of aluminum template leftover materials with different lengths can be produced in the processing process of the aluminum template, and the prior art can only process parts with smaller sizes than the aluminum template leftover materials on the basis of the aluminum template leftover materials, but because the parts with smaller sizes are less in demand, the parts with smaller sizes can be more than the aluminum template leftover materials. The leftover materials need to be removed, but the current cutting mechanism for the leftover materials only pulls the leftover materials downwards, so that the leftover materials are separated, but the separation effect is poor, the situation that the leftover materials cannot be thoroughly separated exists, and partial finished products are wound together with the leftover materials, so that waste is caused.

Disclosure of Invention

In order to solve the problems in the prior art, the invention provides an aluminum template cutting device, which comprises a cutting device body, wherein the cutting device body is provided with an imprinting device and a material guide mechanism, and the material guide mechanism passes through the lower part of an output end of the imprinting device; the device comprises a stamping device, a discharging mechanism, a separating mechanism, a discharging mechanism and a recycling mechanism, wherein the recycling mechanism and the discharging mechanism are positioned at one side of the output end of the material guiding mechanism, the separating mechanism is positioned between the stamping device and the discharging mechanism, the separating mechanism is arranged below the material guiding mechanism, and the discharging mechanism is positioned above the separating mechanism;

the separating mechanism comprises an inner shell, a driving module, a circulating belt and a push rod; the inner shell comprises a base, a protruding part and a magnetic attraction layer, the cross section of the base is in a straight notch shape, the protruding part is arranged at the upper end of the base, the height of the protruding part gradually increases from one end close to the imprinting device to the other end and gradually decreases, and the magnetic attraction layer surrounds the outer periphery of the inner shell; the circulating belt is arranged on the outer side of the inner shell in a surrounding mode;

the output end of the driving module is connected with the circulating belt and used for driving the circulating belt to circularly rotate along the periphery of the inner shell in the material conveying direction; the circulating belt is provided with a plurality of sliding grooves in a penetrating mode, the ejector rod is connected with the sliding grooves in a sliding mode, and the lower end of the ejector rod is in sliding contact with the outer side of the magnetic attraction layer;

when the circulating belt drives the ejector rod to move to the top end of the protruding portion, the upper end of the ejector rod moves upwards from the port of the sliding groove, and the stamped object passing through the upper material guiding mechanism is ejected into the input end of the discharging mechanism.

Further scheme is, the lower extreme of cutting device body is provided with a plurality of and is used for right cutting device body carries out absorbing damper, damper includes:

the damping support seat is arranged below the cutting device body and supports the cutting device body;

the vibration power generation mechanism is arranged on the vibration absorption supporting seat and generates power through vibration of the vibration absorption supporting seat.

Further scheme is, the shock attenuation supporting seat includes:

the base is fixed on the ground and provided with a vertical sliding groove;

the sliding support rod is in sliding fit with the base;

the fixed block is arranged on the sliding support rod;

the fixed ring is fixed on the lower end face of the cutting device body, and the outer side of the fixed ring is connected with the sliding supporting rod;

the buffering elastic piece is sleeved on the sliding support rod and is positioned between the fixing blocks and the base.

Further, the vibration power generation mechanism comprises:

the permanent magnets are fixed on two sides of the base, and the magnetic field generated by the permanent magnets covers the buffer elastic piece and the position of the fixed block;

and the upper part of the inner side of the coil is fixed on the fixed block.

The embossing device comprises a main frame, wherein the upper end of the main frame is provided with a telescopic cylinder group, and the output end of the telescopic cylinder group is vertically downward and fixedly connected with an embossing block; the guide mechanism comprises a bottom plate and guide components, the bottom plate is arranged below the stamping block, and the guide components are symmetrically arranged on two sides of the bottom plate; the guide assembly comprises a guide conveying belt and a driving wheel set, and the driving wheel set is connected with the guide conveying belt and used for driving the guide conveying belt to run.

Further, the baffle is arranged on one side of the guide conveying belt away from the bottom plate, the pressing roller is arranged above the guide conveying belt, and the pressing roller is arranged on the baffle.

The further scheme is, the drive module includes runner, pivot and belt drive group, the pivot rotate set up in both ends around the inner shell, the runner symmetry set up in the both ends of pivot, belt drive group's output is connected with the pivot of one side, the endless belt with the runner rotates to be connected.

The lower end of the ejector rod is provided with a groove, a magnetic ball is rotationally connected with the groove, and the magnetic ball is in rolling connection with the magnetic attraction layer.

The discharging mechanism comprises a connecting plate and a discharging transmission belt group, one end of the connecting plate is arranged at one side of the input end of the discharging transmission belt group, and the other end extends to the upper part of the separating mechanism; the connecting plate is obliquely arranged.

Further, the recycling mechanism comprises a traction roller set and a recycling box, and the recycling box is arranged below the traction roller set.

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

according to the aluminum template cutting device provided by the invention, the ejector rod is driven to move along the surface of the inner shell by the rotating circulating belt, and when the ejector rod passes through the convex part, the embossed objects are ejected upwards and separated along the fluctuation, and meanwhile, the ejected embossed objects are transferred. Meanwhile, the residual leftover materials are pressed on the material guide mechanism, so that the die-cut materials are separated from the upper direction and the lower direction respectively, and the separation effect is better and the accuracy is higher.

According to the invention, the vibration absorbing mechanism is arranged, so that the cutting device body is supported, and meanwhile, when the cutting device body vibrates during operation or the cutting device body vibrates due to external impact force, the cutting device body transmits the vibration to the fixed block in the vibration absorbing support seat, the fixed block vibrates up and down, and vibration energy generated during operation of the cutting device body can be buffered through the vibration absorbing mechanism. Meanwhile, the vibration power generation mechanism is arranged on the vibration-absorbing supporting seat, so that the vibration-absorbing supporting seat can generate power in the vibration process, the energy utilization rate is improved, and the power generation efficiency is improved.

Drawings

Fig. 1 is a front view of an aluminum die plate cutting device according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a shock-absorbing support seat according to an embodiment of the present invention:

FIG. 3 is an enlarged schematic view of FIG. 1 at A;

FIG. 4 is a partial schematic view of the upper side of a endless belt of a provider of an embodiment of the present invention;

fig. 5 is a schematic structural view of a cutting device according to an embodiment of the present invention when die-cutting is performed.

The drawings are marked: 1-a cutting device body; 2-embossing means; 20-a main frame; 21-a telescopic cylinder group; 22-embossing blocks; 23-baffle; 24-pressing the roller; 3-a material guiding mechanism; 30-a bottom plate; 31-a guide assembly; 310-a material guiding conveyor belt; 311-driving the wheel set; 4-a separation mechanism; 40-an inner shell; 400-base; 401-a boss; 402-a magnetic attraction layer; 41-a driving module; 410-turning wheel; 411-rotating shaft; 412-belt drive set; 42-circulating belt; 420-a chute; 43-ejector rod; 430-grooves; 431-magnetic balls; 5-a discharging mechanism; 50-a splice plate; 51-a discharge conveyor belt group; 6-a recovery mechanism; 60-pulling roll set; 61-a recovery box; 7-a damping supporting seat; 70-a base; 71-sliding support rods; 72-fixing blocks; 73-a fixing ring; 74-a cushioning elastic member; 8-a vibration power generation mechanism; 80-permanent magnet; 81-coil.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

As shown in fig. 1-5, an embodiment of the present invention discloses an aluminum template cutting device, which comprises a cutting device body 1, wherein the cutting device body 1 is provided with an embossing device 2 and a material guiding mechanism 3, and the material guiding mechanism 3 passes through the lower part of an output end of the embossing device 2; the device also comprises a separating mechanism 4, a discharging mechanism 5 and a recycling mechanism 6, wherein the recycling mechanism 6 and the discharging mechanism 5 are positioned at one side of the output end of the material guiding mechanism 3, the separating mechanism 4 is positioned between the embossing device 2 and the discharging mechanism 5, the separating mechanism 4 is arranged below the material guiding mechanism 3, and the discharging mechanism 5 is positioned above the separating mechanism 4;

after entering from the input end of the material guiding mechanism, the material is imprinted into semi-separated indentations by the imprinting device, and the imprinted material and the rest material are separated by the separating mechanism.

The separating mechanism 4 comprises an inner shell 40, a driving module 41, a circulating belt 42 and a push rod 43; the inner shell 40 comprises a base 400, a protruding part 401 and a magnetic attraction layer 402, the cross section of the base 400 is in a straight notch shape, the protruding part 401 is arranged at the upper end of the base 400, the height of the protruding part 401 gradually increases from one end close to the imprinting device 2 to the other end, then gradually decreases, and the magnetic attraction layer 402 surrounds the outer periphery of the inner shell 400; the circulating belt 42 is disposed around the outside of the inner case 400;

wherein, the circulating belt and the base are arranged at equal intervals.

The output end of the driving module 41 is connected with the circulating belt 42, and is used for driving the circulating belt 42 to circularly rotate along the periphery of the inner shell 40 in the material conveying direction; a plurality of sliding grooves 420 are arranged on the circulating belt 42 in a penetrating manner, the ejector rod 43 is connected with the sliding grooves 420 in a sliding manner, and the lower end of the ejector rod 43 is propped against the outer side of the magnetic attraction layer 402 in a sliding manner;

when the circulating belt of the embodiment runs and rotates, the ejector rod arranged in the chute moves along with the circulating belt, and when the ejector rod moves above the protruding part, the ejector rod moves upwards due to the fluctuation of the protruding part, and when the circulating belt drives the ejector rod to move to the top end of the protruding part, the upper end of the ejector rod moves upwards from the port of the chute, and the imprinting object passing through the upper material guide mechanism is ejected into the input end of the discharging mechanism. Wherein, can install the ejector pin in the spout on different positions according to different figures.

When the endless belt 42 drives the ejector rod 43 to move to the top end of the protruding portion 401, the upper end of the ejector rod 43 moves upward from the port of the chute 420, and pushes the embossed object passing through the upper material guiding mechanism 3 into the input end of the material discharging mechanism 5.

The aluminum template cutting device of the embodiment comprises the following steps when in use:

step S1: after the material is put into the cutting device from the input end of the material guide mechanism, the cutting device body is started for debugging and setting, and a push rod is arranged at a proper position on the circulating belt;

step S2: when the material passes below the embossing device, the embossing block is driven by the telescopic cylinder group to emboss an embossed object on the material, and the embossed object continuously moves forwards;

step S3: the driving module drives the circulating belt to circularly rotate, meanwhile, the ejector rod is driven to move on the surface of the magnetic attraction layer, two sides of a material are pressed by the pressing roller, meanwhile, the ejector rod pushes an embossed object onto the connecting plate along with upward movement of the protruding part, and meanwhile, the embossed object is gradually separated from the material along with integral separation of the embossed object, and enters the discharging conveying belt group to be transported away;

step S4: and meanwhile, the residual materials from which the stamped objects are separated are guided to a recovery box along with the traction roller set for collection.

In this embodiment, the lower end of the cutting device body 1 is provided with a plurality of shock absorbing mechanisms for absorbing shock to the cutting device body 1, the shock absorbing mechanisms include:

the damping support seat 7 is arranged below the cutting device body 1, and the damping support seat 7 supports the cutting device body 1;

the vibration power generation mechanism 8, the vibration power generation mechanism 8 is arranged on the vibration damping supporting seat 7 and generates power through the vibration of the vibration damping supporting seat 7.

In the embodiment, the damping mechanism is arranged below the cutting device body, and vibration energy generated during the operation of the cutting device body is buffered through the damping mechanism. Meanwhile, the vibration power generation mechanism is arranged on the vibration-absorbing supporting seat, so that the vibration-absorbing supporting seat can generate power in the vibration process, the energy utilization rate is improved, and the power generation efficiency is improved.

In the present embodiment, the shock-absorbing support base 7 includes:

the base 70, the base 70 is fixed on the ground, the base 70 is provided with a vertical sliding groove;

a sliding support bar 71, the sliding support bar 71 being slidably fitted on the base 70;

a fixed block 72, the fixed block 72 being provided on the slide support bar 71;

the fixed ring 73, the fixed ring 73 is fixed on the lower end surface of the cutting device body 1, the outside of the fixed ring 73 is connected with the sliding support rod 71;

the buffer elastic member 74 is sleeved on the sliding support rod 71, and the buffer elastic member 74 is located between the fixing block 72 and the base 70.

It should be noted that, the buffer elastic member of the present embodiment may have an elastic structure such as a spring and a shrapnel. When the cutting device body vibrates during operation or the cutting device body vibrates due to external impact force, the buffering elastic piece can play a role in buffering, and vibration of the cutting device body is relieved.

In the present embodiment, the vibration power generation mechanism 8 includes:

permanent magnets 80, the permanent magnets 80 are fixed on both sides of the base 70, and the magnetic field generated by the permanent magnets 80 covers the buffer elastic member 74 and the fixing block 72;

and a coil 81, wherein an upper portion of the inner side of the coil 81 is fixed to the fixing block 72.

When the cutting device body vibrates due to vibration generated during operation or external impact force applied to the cutting device body, the cutting device body transmits the vibration to the fixed block in the damping support seat, the fixed block vibrates up and down, the coil fixed on the fixed block moves up and down, the coil is further enabled to cut a magnetic induction line generated by permanent magnets on two sides, and current is further generated in the coil. The coil of this embodiment may be connected by wires to the device or equipment to be powered. So that the current generated in the coil supplies power to the device to be powered through the wire. The embodiment improves the utilization rate of energy and the power generation efficiency by vibration power generation.

In this embodiment, the imprinting device 2 includes a main frame 20, a telescopic cylinder group 21 is disposed at the upper end of the main frame 20, and an output end of the telescopic cylinder group 21 is vertically downward and fixedly connected with an imprinting block 22; the material guide mechanism 3 comprises a bottom plate 30 and guide components 31, the bottom plate 30 is arranged below the stamping block 22, and the guide components 31 are symmetrically arranged on two sides of the bottom plate 30; the guiding assembly 31 comprises a guiding conveying belt 310 and a driving wheel set 311, wherein the driving wheel set 311 is connected with the guiding conveying belt 310 to drive the guiding conveying belt 310 to run.

The drive wheelset drive guide conveyer belt of this embodiment moves, and when the material on the guide conveyer belt passed through, promotes the impression piece through flexible cylinder group and imprints the material, and wherein the bottom plate plays the effect of support when the impression.

In this embodiment, a baffle 23 is disposed on a side of the guide conveyor 20 away from the bottom plate 30, a pressing roller 24 is disposed above the guide conveyor 310, and the pressing roller 24 is mounted on the baffle 23.

According to the embodiment, the material can move between the material guiding conveying belt and the pressing roller through the arrangement, the material can be positioned through the pressing roller, and when the ejector rod ejects the pressing object upwards, the pressing roller presses the leftover downwards, so that the material can be separated from the material by the pressing roller.

In this embodiment, the driving module 41 includes a rotating wheel 410, a rotating shaft 411 and a belt driving set 412, the rotating shaft 411 is rotatably disposed at the front and rear ends of the inner housing 40, the rotating wheel 410 is symmetrically disposed at the two ends of the rotating shaft 411, the output end of the belt driving set 412 is connected with the rotating shaft 411 at one side, and the circulating belt 42 is rotatably connected with the rotating wheel 410.

The belt driving group can drive the rotating shaft to rotate through the arrangement, and meanwhile, the rotating wheel is rotated, so that the circulating belt can run.

In this embodiment, a groove 430 is disposed at the lower end of the ejector rod 43, a magnetic ball 431 is rotatably connected to the groove 430, and the magnetic ball 431 is in rolling connection with the magnetic attraction layer 402.

According to the embodiment, the magnetic balls are arranged at the bottom end of the ejector rod, so that the ejector rod can move smoothly, and meanwhile, the bottom end of the ejector rod always moves on the surface of the magnetic attraction layer through magnetic connection between the magnetic attraction layer and the magnetic balls.

In this embodiment, the discharging mechanism 5 includes a connecting plate 50 and a discharging conveyor belt group 51, one end of the connecting plate 50 is arranged at one side of the input end of the discharging conveyor belt group 51, and the other end extends to the upper part of the separating mechanism 4; the connector plate 50 is disposed obliquely.

According to the embodiment, when the ejector rod is propped against the stamped object to be separated, the separated part of the front end of the stamped object is higher than the lower end of the connecting plate, and when the pressed object is not completely separated, the pressed object still advances, and finally is in contact with the discharging conveyor belt group to be completely separated and transported away.

In the present embodiment, the recovery mechanism 6 includes a pulling roller group 60 and a recovery tank 61, and the recovery tank 61 is provided below the pulling roller group 60.

According to the embodiment, through the arrangement, the traction roller group can be used for carrying out traction and guide on the residual materials from which the stamped objects are separated to the recovery box, so that the materials are ensured to be stable in the moving process.

Finally, only specific embodiments of the present invention have been described in detail above. The invention is not limited to the specific embodiments described above. Equivalent modifications and substitutions of the invention will occur to those skilled in the art, and are intended to be within the scope of the present invention. Accordingly, equivalent changes and modifications are intended to be included within the scope of the present invention without departing from the spirit and scope thereof.

Claims (7)

1. An aluminum template cutting device, includes cutting device body (1), its characterized in that:

the cutting device comprises a cutting device body (1), a pressing device (2) and a guide mechanism (3), wherein the guide mechanism (3) penetrates through the lower part of an output end of the pressing device (2); the device comprises a material guiding mechanism (3), and is characterized by further comprising a separating mechanism (4), a discharging mechanism (5) and a recycling mechanism (6), wherein the recycling mechanism (6) and the discharging mechanism (5) are positioned at one side of the output end of the material guiding mechanism (3), the separating mechanism (4) is positioned between the imprinting device (2) and the discharging mechanism (5), the separating mechanism (4) is arranged below the material guiding mechanism (3), and the discharging mechanism (5) is positioned above the separating mechanism (4);

the separating mechanism (4) comprises an inner shell (40), a driving module (41), a circulating belt (42) and a push rod (43); the inner shell (40) comprises a base (400), a protruding part (401) and a magnetic attraction layer (402), the cross section of the base (400) is in a straight notch shape, the protruding part (401) is arranged at the upper end of the base (400), the height of the protruding part (401) gradually increases from one end close to the imprinting device (2) to the other end and gradually decreases, and the magnetic attraction layer (402) surrounds the outer periphery of the inner shell (40); the circulating belt (42) is arranged on the outer side of the inner shell (40) in a surrounding manner;

the output end of the driving module (41) is connected with the circulating belt (42) and is used for driving the circulating belt (42) to circularly rotate along the periphery of the inner shell (40) in the material conveying direction; a plurality of sliding grooves (420) are formed in the circulating belt (42) in a penetrating mode, the ejector rods (43) are connected with the sliding grooves (420) in a sliding mode, and the lower ends of the ejector rods (43) are in sliding contact with the outer side of the magnetic attraction layer (402);

when the circulating belt (42) drives the ejector rod (43) to move to the top end of the protruding part (401), the upper end of the ejector rod (43) moves upwards from the port of the chute (420) and pushes the stamped matters passing through the upper material guide mechanism (3) into the input end of the discharging mechanism (5);

the lower extreme of cutting device body (1) is provided with a plurality of and is used for carrying out absorbing damper to cutting device body (1), damper includes:

the damping support seat (7), the damping support seat (7) is arranged below the cutting device body (1), and the damping support seat (7) supports the cutting device body (1);

the vibration power generation mechanism (8) is arranged on the vibration absorption supporting seat (7) and generates power through the vibration of the vibration absorption supporting seat (7);

the shock-absorbing support base (7) comprises:

the base (70), the said base (70) is fixed on ground, offer the vertical sliding groove on the said base (70);

a sliding support rod (71), wherein the sliding support rod (71) is in sliding fit on the base (70);

a fixed block (72), wherein the fixed block (72) is arranged on the sliding support rod (71);

the fixed ring (73), the fixed ring (73) is fixed on the lower end face of the cutting device body (1), and the outer side of the fixed ring (73) is connected with the sliding supporting rod (71);

the buffering elastic piece (74), the buffering elastic piece (74) is sleeved on the sliding supporting rod (71), and the buffering elastic piece (74) is located between the fixing blocks (72) and the base (70);

the vibration power generation mechanism (8) comprises:

the permanent magnets (80) are fixed on two sides of the base (70), and the magnetic field generated by the permanent magnets (80) covers the buffer elastic piece (74) and the positions of the fixed blocks (72);

and a coil (81), wherein an upper portion of the inside of the coil (81) is fixed to the fixed block (72).

2. An aluminum die plate cutting device as claimed in claim 1, wherein:

the embossing device (2) comprises a main frame (20), wherein a telescopic cylinder group (21) is arranged at the upper end of the main frame (20), and an embossing block (22) is vertically downwards and fixedly connected with the output end of the telescopic cylinder group (21); the material guiding mechanism (3) comprises a bottom plate (30) and guiding components (31), the bottom plate (30) is arranged below the stamping block (22), and the guiding components (31) are symmetrically arranged on two sides of the bottom plate (30); the guide assembly (31) comprises a guide conveying belt (310) and a driving wheel set (311), and the driving wheel set (311) is connected with the guide conveying belt (310) and used for driving the guide conveying belt (310) to run.

3. An aluminum die plate cutting device as claimed in claim 2, wherein:

one side of the guide conveying belt (310) far away from the bottom plate (30) is provided with a baffle plate (23), a pressing roller (24) is arranged above the guide conveying belt (310), and the pressing roller (24) is arranged on the baffle plate (23).

4. An aluminum die plate cutting device as claimed in claim 1, wherein:

the driving module (41) comprises a rotating wheel (410), a rotating shaft (411) and a belt driving group (412), wherein the rotating shaft (411) is rotatably arranged at the front end and the rear end of the inner shell (40), the rotating wheel (410) is symmetrically arranged at the two ends of the rotating shaft (411), the output end of the belt driving group (412) is connected with the rotating shaft (411) at one side, and the circulating belt (42) is rotatably connected with the rotating wheel (410).

5. An aluminum die plate cutting device as claimed in claim 1, wherein:

the lower extreme of ejector pin (43) is provided with recess (430), recess (430) swivelling joint has magnetic ball (431), magnetic ball (431) with magnetic layer (402) roll connection.

6. An aluminum die plate cutting device as claimed in claim 1, wherein:

the discharging mechanism (5) comprises a connecting plate (50) and a discharging transmission belt group (51), one end of the connecting plate (50) is arranged at one side of the input end of the discharging transmission belt group (51), and the other end extends to the upper part of the separating mechanism (4); the connecting plate (50) is obliquely arranged.

7. An aluminum die plate cutting device as claimed in claim 1, wherein:

the recovery mechanism (6) comprises a traction roller set (60) and a recovery box (61), and the recovery box (61) is arranged below the traction roller set (60).