CN113021061A - Intelligent cutting manufacturing equipment - Google Patents

Abstract

The invention relates to cutting equipment, in particular to intelligent cutting and manufacturing equipment which comprises a linkage cutting mechanism, a cutting platform mechanism and a vibration packing mechanism, wherein the equipment can cut and simultaneously complete the treatment of cutting scraps, can drain the scraps, can feed raw materials to be cut, can pack the scraps, is connected with the cutting platform mechanism, and is connected with the vibration packing mechanism.

Description

Intelligent cutting manufacturing equipment

Technical Field

The invention relates to cutting equipment, in particular to intelligent cutting manufacturing equipment.

Background

In the cutting manufacturing process, the raw material needs to be cut, and the traditional cutting equipment cannot achieve multi-step coordinated operation through good design of the traditional cutting equipment, so that intelligent control becomes more difficult, and the intelligent cutting manufacturing equipment is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing intelligent cutting manufacturing equipment, wherein the equipment can cut and simultaneously complete the treatment of cutting scraps, can drain the scraps, can feed raw materials to be cut, and can pack the scraps.

In order to solve the technical problem, the invention relates to a cutting device, in particular to an intelligent cutting and manufacturing device which comprises a linkage cutting mechanism, a cutting platform mechanism and a vibration packing mechanism.

The linkage cutting mechanism is connected with the cutting platform mechanism, and the cutting platform mechanism is connected with the vibration packaging mechanism.

As a further optimization of the technical scheme, the linkage cutting mechanism of the intelligent cutting manufacturing equipment comprises supporting legs, a supporting table, a motor, a belt, a bearing seat, a cam with a shaft, an air inlet, a filter plate groove, an air box, a friction wheel with a shaft, a movable frame with a hole, a hose, a hard pipe, a connecting box, an air bag, a connecting pipe, a supporting seat, a polished rod, a spring, a bidirectional screw rod with a twisting head, a bearing seat I, a threaded limit sliding block, a matching groove, a belt pulley with a shaft, a belt I, a motor belt pulley, a cutting knife, a pipe orifice, a motor belt pulley I, a wind wheel, a sliding groove, an embedded groove, a driving motor and an inner spray pipe, wherein the supporting legs are connected with the supporting table, the supporting table is connected with the motor, the motor is connected with the motor belt pulley I, the motor, the belt shaft cam is rotationally connected with a bearing seat, the bearing seat is connected with a support table, the belt shaft cam is contacted with a belt shaft friction wheel, an air inlet and a filter plate groove are arranged on an air box, a filter plate is slidably connected with the filter plate groove, the air box is connected with a movable frame with holes, the movable frame with holes is connected and communicated with a hose, the hose is connected and communicated with a hard pipe, the hard pipe is connected and communicated with a connecting box, the connecting box is connected and communicated with a connecting pipe, the connecting pipe is connected and communicated with an air bag, an inner spray pipe is connected and communicated with the air bag, the connecting pipe penetrates through a supporting seat, the supporting seat is connected with a polished rod, the polished rod is connected with the support table, a spring is sleeved on the polished rod, two ends of the spring are respectively connected with the supporting seat and the movable frame with holes, the movable frame with the polished rod is slidably connected, a bidirectional screw, threaded limiting sliding block and cooperation groove sliding connection, the cooperation groove sets up on the tape spool belt pulley, tape spool belt pulley and belt I friction joint, belt I and motor pulley friction joint, motor pulley links to each other with driving motor, driving motor links to each other with foraminiferous adjustable shelf, be equipped with the spout on the cutting knife, spout and tape spool belt pulley sliding connection, tape spool belt pulley rotates with foraminiferous adjustable shelf to be connected, the mouth of pipe sets up on the connecting pipe, the wind wheel links to each other with tape spool friction pulley, tape spool friction pulley rotates with foraminiferous adjustable shelf to be connected, tape spool friction pulley rotates with bellows to be connected, the embedded groove sets up on the cutting knife, embedded groove and threaded limiting sliding block sliding connection.

As a further optimization of the technical scheme, the cutting platform mechanism of the intelligent cutting manufacturing equipment comprises a base, a supporting leg I, an upper platform, a speed reducing box, a belt II, a belt pulley II, an inlet port, a baffle, a cutting supporting platform, a hinged arm I, a hinged joint, a hydraulic cylinder support, a U-shaped pipe, a motor base, a recovery motor, a transmission belt pulley, a bellows I, an outlet, a step connecting pipe, a stall scraping wheel, a drainage belt shaft wind wheel, an inner sliding rod, a sliding chute I, a reset spring and a drainage channel, wherein the base is connected with the supporting leg I, the supporting leg I is connected with the upper platform, the upper platform is connected with the speed reducing box, the inlet port is arranged on the upper platform, the inlet port is communicated with the stall box, the baffle is connected with the cutting supporting platform, the cutting supporting platform is hinged with the hinged arm, the articulated arm I is articulated with an articulated joint, the articulated joint is connected with a hydraulic cylinder, the hydraulic cylinder is articulated with a hydraulic cylinder support, the hydraulic cylinder support is connected with an upper platform, a U-shaped pipe is communicated with a drainage channel arranged on the upper platform, the U-shaped pipe is connected with the upper platform, the upper platform is connected with a motor base, the motor base is connected with a recovery motor, the recovery motor is connected with a transmission belt pulley, the transmission belt pulley is in friction connection with a belt II, the belt II is in friction connection with a belt pulley II, an air box I is connected with the upper platform, the air box I is communicated with a stall box through a step connecting pipe, an outlet is arranged on the stall box, the stall wheel is connected with the belt pulley II, the stall wheel is in rotation connection with the stall box, a drainage belt shaft wind wheel is in rotation connection with the air box I, the drainage belt shaft wind wheel is connected with the transmission belt pulley, the reset spring is sleeved on the inner sliding rod, the two ends of the reset spring are respectively connected to the upper platform and the cutting support platform, the cutting support platform is connected with the inner sliding rod in a sliding mode, the cutting support platform is connected with the sliding groove I in a sliding mode, and the supporting legs, the connecting box and the supporting seat are all connected with the upper platform wedge block.

As a further optimization of the technical scheme, the vibrating and packaging mechanism of the intelligent cutting and manufacturing equipment comprises a discharge pipe, a side pressing seat, a limiting square column, a bidirectional screw rod, a servo motor and a collecting hopper, the device comprises a limiting connecting plate, a porous floating frame, a sliding column, a self-vibrating spring, a lower support frame, a discharge pipe, a side pressing seat, a limiting square column, a bidirectional screw rod, a side pressing seat, a bidirectional screw rod, a servo motor, a base, a self-vibrating spring sleeve and a self-vibrating spring, wherein the discharge pipe is connected and communicated with a collecting hopper, the side pressing seat is connected with the limiting square column in a sliding manner, the limiting square column is connected with the collecting hopper, the bidirectional screw rod is in threaded connection with the side pressing seat, the bidirectional screw rod is in rotary connection with the collecting hopper, the servo motor is connected with the bidirectional screw rod, the collecting hopper is connected with the porous floating frame, the porous floating.

As a further optimization of the technical scheme, the collecting hopper of the intelligent cutting manufacturing equipment is made of high manganese steel.

The intelligent cutting manufacturing equipment has the beneficial effects that:

according to the intelligent cutting manufacturing equipment, the equipment can cut and simultaneously complete the processing of cutting scraps, the equipment can conduct drainage on the scraps, the equipment can feed raw materials to be cut, and the equipment can pack the scraps.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic structural diagram of an intelligent cutting manufacturing device according to the present invention.

Fig. 2 is a schematic structural diagram of an intelligent cutting manufacturing apparatus according to the present invention.

Fig. 3 is a schematic structural diagram three of the intelligent cutting manufacturing equipment of the invention.

Fig. 4 is a first structural schematic diagram of the linkage cutting mechanism 1 of the intelligent cutting manufacturing equipment of the invention.

Fig. 5 is a second schematic structural diagram of the linkage cutting mechanism 1 of the intelligent cutting manufacturing equipment of the invention.

Fig. 6 is a third schematic structural diagram of the linkage cutting mechanism 1 of the intelligent cutting manufacturing equipment of the invention.

Fig. 7 is a first schematic structural diagram of the cutting platform mechanism 2 of the intelligent cutting manufacturing equipment of the invention.

Fig. 8 is a second schematic structural diagram of the cutting platform mechanism 2 of the intelligent cutting manufacturing equipment of the invention.

Fig. 9 is a third schematic structural diagram of the cutting platform mechanism 2 of the intelligent cutting manufacturing equipment of the invention.

Fig. 10 is a fourth schematic structural diagram of the cutting platform mechanism 2 of the intelligent cutting manufacturing equipment of the invention.

Fig. 11 is a first structural schematic diagram of the vibration packing mechanism 3 of the intelligent cutting manufacturing equipment according to the present invention.

In the figure: a linkage cutting mechanism 1; 1-1 of supporting legs; a support table 1-2; 1-3 of a motor; 1-4 parts of a belt; 1-5 of a bearing seat; 1-6 of cam with shaft; 1-7 of an air inlet; 1-8 parts of a filter plate; 1-9 parts of filter plate grooves; 1-10 of an air box; 1-11 of friction wheel with shaft; 1-12 of movable frame with holes; 1-13 of flexible pipe; 1-14 parts of hard pipe; 1-15 of a connecting box; 1-16 of air bags; connecting pipes 1-17; 1-18 parts of a supporting seat; 1-19 parts of a polished rod; 1-20 parts of spring; a bidirectional screw 1-21 with a twisting head; bearing seats I1-22; 1-23 of a limiting sliding block with threads; 1-24 of a matching groove; belt pulley 1-25 with axle; belts I1-26; motor belt pulleys 1-27; 1-28 parts of cutting knife; 1-29 parts of pipe orifice; a motor pulley I1-30; pulley I1-31; 1-32 parts of wind wheel; 1-33 of a chute; embedded grooves 1-34; driving motors 1-35; 1-36 parts of inner spray pipe; a cutting platform mechanism 2; a base 2-1; leg I2-2; 2-3 of an upper platform; 2-4 of a speed reducing box; belt II 2-5; pulley II 2-6; an inlet 2-7; 2-8 parts of baffle plates; cutting the support table 2-9; articulated arms 2-10; articulated arm I2-11; joints 2-12; 2-13 of a hydraulic cylinder; 2-14 of hydraulic cylinder support; 2-15 parts of a U-shaped pipe; 2-16 of a motor base; recovering the motors 2-17; 2-18 of a driving belt pulley; air boxes I2-19; 2-20 of an outlet; 2-21 of a step connecting pipe; stall scraping wheels 2-22; 2-23 of a wind wheel with a drainage belt shaft; 2-24 parts of inner sliding rod; a chute I2-25; 2-26 of a return spring; drainage channels 2-27; vibrating the packaging mechanism 3; a discharge pipe 3-1; 3-2 of a side pressing seat; 3-3 of a limiting square column; 3-4 parts of a bidirectional screw rod; 3-5 of a servo motor; 3-6 of a collecting bucket; 3-7 of a limiting connecting plate; 3-8 of floating frame with holes; 3-9 parts of a sliding column; 3-10 parts of self-vibration spring; and 3-11 parts of a lower support frame.

Detailed Description

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, and fig. 11, and the present invention relates to a cutting apparatus, and more specifically, to an intelligent cutting and manufacturing apparatus, which includes a linkage cutting mechanism 1, a cutting platform mechanism 2, and a vibration packing mechanism 3, and is capable of completing processing of cutting scraps while cutting, draining the scraps, feeding a raw material to be cut, and packing the scraps.

The linkage cutting mechanism 1 is connected with the cutting platform mechanism 2, and the cutting platform mechanism 2 is connected with the vibration packing mechanism 3.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, and the present embodiment further describes the present embodiment, in which the linkage cutting mechanism 1 includes a leg support 1-1, a support table 1-2, a motor 1-3, a belt 1-4, a bearing seat 1-5, a cam with a shaft 1-6, an air inlet 1-7, a filter plate 1-8, a filter plate groove 1-9, an air box 1-10, a friction wheel with a shaft 1-11, a movable frame with a hole 1-12, a hose 1-13, a hard pipe 1-14, a connection box 1-15, an air bag 1-16, a connection pipe 1-17, a support seat 1-18, a polish rod 1-19, a spring 1-20, a bidirectional screw rod 1-21 with a screw head, Bearing seats I1-22, threaded limit slide blocks 1-23, matching grooves 1-24, belt shaft belt pulleys 1-25, belts I1-26, motor belt pulleys 1-27, cutting knives 1-28, nozzles 1-29, motor belt pulleys I1-30, belt pulleys I1-31, wind wheels 1-32, sliding grooves 1-33, embedded grooves 1-34, driving motors 1-35 and inner spraying pipes 1-36, support legs 1-1 are connected with support tables 1-2, the support tables 1-2 are connected with motors 1-3, the motors 1-3 are connected with motor belt pulleys I1-30, motor belt pulleys I1-30 are connected with the belts 1-4 in a friction mode, the belts 1-4 are connected with the belt pulleys I1-31 in a friction mode, belt pulleys I1-31 are connected with belt shaft cams 1-6, the cam with the shaft 1-6 is rotationally connected with the bearing seat 1-5, the bearing seat 1-5 is connected with the supporting table 1-2, the cam with the shaft 1-6 is contacted with the friction wheel with the shaft 1-11, the air inlet 1-7 and the filter plate groove 1-9 are both arranged on the air box 1-10, the filter plate 1-8 is connected with the filter plate groove 1-9 in a sliding way, the air box 1-10 is connected with the movable frame with the hole 1-12, the movable frame with the hole 1-12 is connected and communicated with the hose 1-13, the hose 1-13 is connected and communicated with the hard pipe 1-14, the hard pipe 1-14 is connected and communicated with the connecting box 1-15, the connecting box 1-15 is connected and communicated with the connecting pipe 1-17, the connecting pipe 1-17 is connected and communicated with the air bag 1-16, the inner spray pipe 1-36 is connected, the connecting pipe 1-17 passes through the supporting seat 1-18, the supporting seat 1-18 is connected with the polished rod 1-19, the polished rod 1-19 is connected with the supporting table 1-2, the spring 1-20 is sleeved on the polished rod 1-19, two ends of the spring 1-20 are respectively connected with the supporting seat 1-18 and the movable frame 1-12 with holes, the movable frame 1-12 with holes is connected with the polished rod 1-19 in a sliding way, the bidirectional screw rod 1-21 with a screwing head is connected with the bearing seat I1-22 in a rotating way, the bearing seat I1-22 is connected with the belt pulley 1-25 with a shaft, the bidirectional screw rod 1-21 with the screwing head is connected with the sliding block 1-23 with a thread limiting slide block, the limiting slide block 1-23 with the thread is connected with the matching groove 1-24 in a sliding way, the matching groove 1-, belt shaft pulleys 1-25 are in frictional connection with belts I1-26, the belts I1-26 are in frictional connection with motor pulleys 1-27, the motor pulleys 1-27 are connected with driving motors 1-35, the driving motors 1-35 are connected with movable racks with holes 1-12, cutting knives 1-28 are provided with chutes 1-33, chutes 1-33 are in sliding connection with the belt shaft pulleys 1-25, the belt shaft pulleys 1-25 are in rotational connection with the movable racks with holes 1-12, nozzles 1-29 are arranged on connecting pipes 1-17, wind wheels 1-32 are connected with belt shaft friction wheels 1-11, belt shaft friction wheels 1-11 are in rotational connection with the movable racks with holes 1-12, belt shaft friction wheels 1-11 are in rotational connection with wind boxes 1-10, the cutting knives are embedded in grooves 1-34, the embedded groove 1-34 is connected with the threaded limit sliding block 1-23 in a sliding way, the motor 1-3 and the driving motor 1-35 are synchronously operated, the driving motor 1-35 can drive the belt shaft belt pulley 1-25 to rotate through the belt I1-26, the belt shaft belt pulley 1-25 can drive the cutting knife 1-28 to rotate, the motor 1-3 can drive the motor belt pulley I1-30 to rotate, the motor belt pulley I1-30 can drive the belt pulley I1-31 to rotate through the belt 1-4, the belt pulley I1-31 can drive the belt shaft cam 1-6 to rotate, the belt shaft cam 1-6 drives the belt shaft friction wheel 1-11 to reciprocate up and down through the matching with the spring 1-20 when rotating, and the belt shaft friction wheel 1-11 can self-rotate due to the friction force, the friction wheel 1-11 with the shaft can drive the wind wheel 1-32 to rotate to form wind from top to bottom, the friction wheel 1-11 with the shaft can drive the movable frame 1-12 with the hole to reciprocate up and down, the movable frame 1-12 with the hole can drive the rotating cutting knife 1-28 to reciprocate up and down, thereby completing the cutting action, the wind from top to bottom formed by the rotation of the wind wheel 1-32 enters from the air inlet 1-7, is filtered by the filter plate 1-8, then enters into the air box 1-10 downwards, then enters into the connecting pipe 1-17 through the hose 1-13, the hard pipe 1-14 and the connecting box 1-15, then is blown out from the pipe orifice 1-29, the air bag 1-16 can be repeatedly compressed when the movable frame 1-12 with the hole reciprocates up and down, then the air bag 1-16 can recover deformation, when the air bags 1-16 are compressed, the air in the air bags 1-16 is compressed and then blown out from the inner spray pipes 1-36, so that the air is superposed with the air in the connecting pipes 1-17 to form instant high-pressure air flow, cutting scraps can be blown to the direction of the articulated arm 2-10, the two-way lead screw 1-21 with the twisting head can be twisted by the replacement of the cutting knife 1-28, the two-way lead screw 1-21 with the twisting head can drive the two threaded limiting sliding blocks 1-23 to approach to the center of the belt shaft belt pulley 1-25, and the threaded limiting sliding blocks 1-23 are separated from the embedded grooves 1-34, so that the cutting knife 1-28 can be removed for replacement.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, and this embodiment will be further described, wherein the cutting platform mechanism 2 includes a base 2-1, a leg I2-2, an upper platform 2-3, a speed-loss box 2-4, a belt II2-5, a pulley II2-6, an inlet 2-7, a baffle 2-8, a cutting support 2-9, an articulated arm 2-10, an articulated arm I2-11, an articulated joint 2-12, a hydraulic cylinder 2-13, a hydraulic cylinder support 2-14, a U-shaped tube 2-15, a motor base 2-16, a recovery motor 2-17, a driving pulley 2-18, a bellows I2-19, an outlet 2-20, a step connection tube 2-21, a hydraulic cylinder support 2-14, a U-, Stall scraping wheels 2-22, a wind wheel 2-23 with a drainage belt shaft, an inner slide rod 2-24, a sliding groove I2-25, a return spring 2-26 and a drainage channel 2-27, a base 2-1 is connected with a supporting leg I2-2, the supporting leg I2-2 is connected with an upper platform 2-3, the upper platform 2-3 is connected with a speed-reducing box 2-4, an inlet 2-7 is arranged on the upper platform 2-3, the inlet 2-7 is communicated with the speed-reducing box 2-4, a baffle 2-8 is connected with a cutting supporting platform 2-9, the cutting supporting platform 2-9 is hinged with an articulated arm 2-10, the articulated arm 2-10 is hinged with an articulated arm I2-11, the articulated arm I2-11 is hinged with the upper platform 2-3, the articulated arm I2-11 is hinged with an articulated arm head 2-12, the articulated joint 2-12 is connected with a hydraulic cylinder 2-13, the hydraulic cylinder 2-13 is articulated with a hydraulic cylinder support 2-14, the hydraulic cylinder support 2-14 is connected with an upper platform 2-3, a U-shaped pipe 2-15 is communicated with a drainage channel 2-27 arranged on the upper platform 2-3, the U-shaped pipe 2-15 is connected with the upper platform 2-3, the upper platform 2-3 is connected with a motor base 2-16, the motor base 2-16 is connected with a recovery motor 2-17, the recovery motor 2-17 is connected with a transmission belt pulley 2-18, the transmission belt pulley 2-18 is in friction connection with a belt II2-5, the belt II2-5 is in friction connection with a belt pulley II2-6, an air box I2-19 is connected with the upper platform 2-3, the air box I2-19 is communicated with a stall box 2-4 through a step connecting pipe 2-, an outlet 2-20 is arranged on a stall box 2-4, a stall scraping wheel 2-22 is connected with a belt pulley II2-6, a stall scraping wheel 2-22 is rotationally connected with a stall box 2-4, a flow guide belt shaft wind wheel 2-23 is rotationally connected with a wind box I2-19, a flow guide belt shaft wind wheel 2-23 is connected with a transmission belt pulley 2-18, an inner slide bar 2-24 is connected with an upper platform 2-3, the inner slide bar 2-24 is arranged in a slide groove I2-25, the slide groove I2-25 is arranged on the upper platform 2-3, a return spring 2-26 is sleeved on the inner slide bar 2-24, two ends of the return spring 2-26 are respectively connected with the upper platform 2-3 and a cutting support platform 2-9, the cutting support platform 2-9 is slidably connected with the inner slide bar 2-24, the cutting support platform 2-9 is slidably connected with the slide groove I2-, the supporting legs 1-1, the connecting boxes 1-15 and the supporting seats 1-18 are connected with wedges of the upper platform 2-3, the recovery motors 2-17 are operated to drive the transmission belt pulleys 2-18 to rotate, the transmission belt pulleys 2-18 drive the wind wheels 2-23 of the drainage belt shafts to rotate, the wind wheels 2-23 of the drainage belt shafts can rotate to form wind, the wind blows towards the stall boxes 2-4 in the direction of the wind, negative pressure is formed in the drainage channels 2-27, blown debris is drained into the drainage channels 2-27, enters the wind boxes I2-19 from the U-shaped tubes 2-15, then enters the stall wheels 2-22 to lose speed after being blocked, the belt II2-5 drives the belt pulley II2-6 to rotate when the transmission belt pulleys 2-18 rotate, the belt pulley II2-6 drives the stall wheels 2-22 to rotate, the rotation direction is clockwise seen from the recovery motor 2-17 to the air box I2-19, the rotation of the stall scraper 2-22 can scrape the scraps falling from the inlet 2-7 and the scraps drained from the air box I2-19 together into the outlet 2-20 to fall, at the moment, the speed is lost, the scraps can not cause secondary dust raising and then fall into the collecting hopper 3-6, in order to prevent the hand from being cut, the raw material can be fed to push the articulated head 2-12 through the hydraulic cylinder 2-13, the articulated head 2-12 can drive the articulated arm 2-10 to move through the articulated arm I2-11, the articulated arm 2-10 can drive the cutting support platform 2-9 to move, and the materials can be sent to the lower part of the cutting knife 1-28 to be cut.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10 and fig. 11, and the embodiment is further described, wherein the vibration packing mechanism 3 comprises a discharge pipe 3-1, a side pressing seat 3-2, a limit square column 3-3, a bidirectional screw rod 3-4, a servo motor 3-5, a collection bucket 3-6, a limit connecting plate 3-7, a floating frame with holes 3-8, a sliding column 3-9, a self-vibration spring 3-10, a lower support frame 3-11, the discharge pipe 3-1 is connected and communicated with the collection bucket 3-6, the side pressing seat 3-2 is connected with the limit square column 3-3 in a sliding manner, the limit square column 3-3 is connected with the collection bucket 3-6, the bidirectional screw rod 3-4 is connected with the side pressing seat 3-2 in a threaded manner, a bidirectional screw rod 3-4 is rotationally connected with a collecting bucket 3-6, a servo motor 3-5 is connected with the collecting bucket 3-6, the servo motor 3-5 is connected with the bidirectional screw rod 3-4, the collecting bucket 3-6 is connected with a floating frame with holes 3-8, the floating frame with holes 3-8 is slidably connected with a sliding column 3-9, the sliding column 3-9 is connected with a limit connecting plate 3-7, the sliding column 3-9 is connected with a lower support frame 3-11, the lower support frame 3-11 is connected with a base 2-1, a self-vibration spring 3-10 is sleeved on the sliding column 3-9, two ends of the self-vibration spring 3-10 are respectively connected on the frame with holes 3-8 and the lower support frame 3-11, waste scraps fall into the collecting bucket 3-6, a collecting bag discharge pipe is sleeved on the collecting bucket 3-1 before the device is used, then the servo motor 3-5 is operated to drive the bidirectional screw rod 3-4 to rotate, the bidirectional screw rod 3-4 can drive the side pressing seats 3-2 at the two sides to approach each other and press on the bag, then the scraps can gradually move towards the bag, and the self-vibrating spring 3-10 can be compressed to slightly vibrate, so that the collecting hopper 3-6 can ensure a certain shaking amount, and the material can move more smoothly.

The fifth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, and 11, and the present embodiment will be further described with reference to the first embodiment, in which the collecting hoppers 3 to 6 are made of high manganese steel.

The working principle of the device is as follows: the equipment can complete the treatment of cutting scraps while cutting, synchronously operate the motors 1-3 and the driving motors 1-35, the driving motors 1-35 can drive the belt shaft belt pulleys 1-25 to rotate through the belts I1-26, the belt shaft belt pulleys 1-25 can drive the cutting knives 1-28 to rotate, the motors 1-3 can drive the motor belt pulleys I1-30 to rotate, the motor belt pulleys I1-30 can drive the belt pulleys I1-31 to rotate through the belts 1-4, the belt pulleys I1-31 can drive the belt shaft cams 1-6 to rotate, the belt shaft cams 1-6 drive the belt shaft friction wheels 1-11 to reciprocate up and down through the cooperation with the springs 1-20 when rotating, and the belt shaft friction wheels 1-11 can self-rotate due to the friction force, the friction wheel 1-11 with the shaft can drive the wind wheel 1-32 to rotate to form wind from top to bottom, the friction wheel 1-11 with the shaft can drive the movable frame 1-12 with the hole to reciprocate up and down, the movable frame 1-12 with the hole can drive the rotating cutting knife 1-28 to reciprocate up and down, thereby completing the cutting action, the wind from top to bottom formed by the rotation of the wind wheel 1-32 enters from the air inlet 1-7, is filtered by the filter plate 1-8, then enters into the air box 1-10 downwards, then enters into the connecting pipe 1-17 through the hose 1-13, the hard pipe 1-14 and the connecting box 1-15, then is blown out from the pipe orifice 1-29, the air bag 1-16 can be repeatedly compressed when the movable frame 1-12 with the hole reciprocates up and down, then the air bag 1-16 can recover deformation, when the air bags 1-16 are compressed, the air in the air bags 1-16 is compressed and then blown out from the inner spray pipes 1-36, so that the air is superposed with the air in the connecting pipes 1-17 to form instant high-pressure air flow, cutting scraps can be blown to the direction of the articulated arm 2-10, the two-way lead screw 1-21 with the twisting head can be twisted by replacing the cutting knife 1-28, the two-way lead screw 1-21 with the twisting head can drive the two threaded limiting sliding blocks 1-23 to approach to the center of the belt shaft belt pulley 1-25, and the threaded limiting sliding blocks 1-23 are separated from the embedded grooves 1-34, so that the cutting knife 1-28 can be removed for replacement; the device can drain the waste scraps, the recovery motor 2-17 operates to drive the transmission belt pulley 2-18 to rotate, the transmission belt pulley 2-18 can drive the drainage belt shaft wind wheel 2-23 to rotate, the drainage belt shaft wind wheel 2-23 rotates to form wind, the wind blows towards the stall box 2-4 in the direction of the wind, negative pressure is formed in the drainage channel 2-27, blown scraps are drained into the drainage channel 2-27, then enter the wind box I2-19 from the U-shaped pipe 2-15, then enter the stall scraper 2-22 to lose speed after being blocked, the belt II2-5 drives the belt pulley II2-6 to rotate when the transmission belt pulley 2-18 rotates, the belt pulley II2-6 drives the stall scraper 2-22 to rotate, the rotation direction is clockwise when the wind box looks from the recovery motor 2-17 to the I2-19, the rotation of the stall scraper wheels 2-22 can scrape the scraps falling from the inlet 2-7 and the scraps drained from the air boxes I2-19 into the outlets 2-20 together to fall, and at the moment, the speed is lost, and the scraps cannot cause secondary dust raising and then fall into the collecting hoppers 3-6; the equipment can feed raw materials to be cut, in order to prevent hands from being cut, the raw materials can be fed to push the articulated heads 2-12 through the hydraulic cylinders 2-13, the articulated heads 2-12 can drive the articulated arms 2-10 to move through the articulated arms I2-11, and the articulated arms 2-10 can drive the cutting support tables 2-9 to move, so that the materials can be sent to the positions below the cutting knives 1-28 to be cut; the equipment can pack the sweeps, the sweeps fall into the collecting hopper 3-6, before the equipment is used, the collecting bag is sleeved on the discharge pipe 3-1, then the servo motor 3-5 is operated to drive the bidirectional screw rod 3-4 to rotate, the bidirectional screw rod 3-4 can drive the side pressing seats 3-2 on two sides to mutually approach and press the bag, then the sweeps can gradually move into the bag, and the self-vibrating springs 3-10 can receive compression to slightly vibrate, so that the collecting hopper 3-6 can ensure a certain shaking amount, and the movement of materials is smoother.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (5)

1. The utility model provides an intelligence cutting manufacture equipment, includes linkage cutting mechanism (1), cutting platform mechanism (2), vibrations package mechanism (3), its characterized in that: the linkage cutting mechanism (1) is connected with the cutting platform mechanism (2), and the cutting platform mechanism (2) is connected with the vibration packaging mechanism (3).

2. The smart cut manufacturing device of claim 1, wherein: the linkage cutting mechanism (1) comprises supporting legs (1-1), a supporting table (1-2), a motor (1-3), a belt (1-4), bearing blocks (1-5), a cam with a shaft (1-6), an air inlet (1-7), a filter plate (1-8), a filter plate groove (1-9), an air box (1-10), a friction wheel with a shaft (1-11), a movable frame with a hole (1-12), a hose (1-13), a hard pipe (1-14), a connecting box (1-15), an air bag (1-16), a connecting pipe (1-17), a supporting seat (1-18), a polish rod (1-19), a spring (1-20), a bidirectional screw rod with a twisting head (1-21), a bearing block I (1-22), Threaded limiting sliding blocks (1-23), matching grooves (1-24), belt pulleys (1-25) with shafts, belts I (1-26), motor pulleys (1-27), cutting knives (1-28), pipe orifices (1-29), motor pulleys I (1-30), belt pulleys I (1-31), wind wheels (1-32), sliding grooves (1-33), embedded grooves (1-34), driving motors (1-35) and inner spraying pipes (1-36), supporting legs (1-1) are connected with supporting tables (1-2), the supporting tables (1-2) are connected with motors (1-3), the motors (1-3) are connected with the motor pulleys I (1-30), the motor pulleys I (1-30) are in friction connection with the belts (1-4), the belt (1-4) is in friction connection with a belt pulley I (1-31), the belt pulley I (1-31) is connected with a cam (1-6) with a shaft, the cam (1-6) with the shaft is in rotation connection with a bearing seat (1-5), the bearing seat (1-5) is connected with a supporting table (1-2), the cam (1-6) with the shaft is in contact with a friction wheel (1-11) with the shaft, an air inlet (1-7) and a filter plate groove (1-9) are both arranged on an air box (1-10), a filter plate (1-8) is in sliding connection with the filter plate groove (1-9), the air box (1-10) is connected with a movable frame (1-12) with a hole, the movable frame (1-12) with the hole is connected and communicated with a hose (1-13), the hose (1-13) is connected and communicated with a hard pipe (1-14), the hard tube (1-14) is connected and communicated with the connecting box (1-15), the connecting box (1-15) is connected and communicated with the connecting tube (1-17), the connecting tube (1-17) is connected and communicated with the air bag (1-16), the inner spray tube (1-36) is connected and communicated with the air bag (1-16), the connecting tube (1-17) passes through the supporting seat (1-18), the supporting seat (1-18) is connected with the polish rod (1-19), the polish rod (1-19) is connected with the supporting seat (1-2), the spring (1-20) is sleeved on the polish rod (1-19), two ends of the spring (1-20) are respectively connected on the supporting seat (1-18) and the movable frame with holes (1-12), the movable frame with holes (1-12) is connected with the polish rod (1-19) in a sliding way, the bidirectional screw rod (1-21) with the twisting head is rotationally connected with a bearing seat I (1-22), the bearing seat I (1-22) is connected with a belt pulley (1-25) with a shaft, the bidirectional screw rod (1-21) with the twisting head is in threaded connection with a limiting sliding block (1-23) with a thread, the limiting sliding block (1-23) with the thread is in sliding connection with a matching groove (1-24), the matching groove (1-24) is arranged on the belt pulley (1-25) with the shaft, the belt pulley (1-25) with the shaft is in frictional connection with a belt I (1-26), the belt I (1-26) is in frictional connection with a motor pulley (1-27), the motor pulley (1-27) is connected with a driving motor (1-35), the driving motor (1-35) is connected with a movable frame (1-12) with a hole, a sliding groove (1-33) is arranged on a cutting knife (1-28), the sliding groove (1-33) is connected with a belt pulley (1-25) in a sliding mode, the belt pulley (1-25) with a shaft is connected with a movable frame (1-12) with a hole in a rotating mode, a pipe opening (1-29) is arranged on a connecting pipe (1-17), a wind wheel (1-32) is connected with a friction wheel (1-11) with a shaft, the friction wheel (1-11) with a shaft is connected with the movable frame (1-12) with a hole in a rotating mode, the friction wheel (1-11) with a shaft is connected with a wind box (1-10) in a rotating mode, an embedded groove (1-34) is arranged on the cutting knife (1-28), and the embedded groove (1-34) is connected with a limiting sliding block (1-23) with.

3. The smart cut manufacturing device of claim 1, wherein: the cutting platform mechanism (2) comprises a base (2-1), a supporting leg I (2-2), an upper platform (2-3), a speed reducing box (2-4), a belt II (2-5), a belt pulley II (2-6), an inlet (2-7), a baffle (2-8), a cutting support platform (2-9), an articulated arm (2-10), an articulated arm I (2-11), an articulated joint (2-12), a hydraulic cylinder (2-13), a hydraulic cylinder support (2-14), a U-shaped pipe (2-15), a motor base (2-16), a recovery motor (2-17), a transmission belt pulley (2-18), a bellows I (2-19), an outlet (2-20), a stepped connecting pipe (2-21), a stall scraper wheel (2-22), A wind wheel (2-23) with a shaft for drainage, an inner sliding rod (2-24), a sliding chute I (2-25), a reset spring (2-26) and a drainage channel (2-27), wherein a base (2-1) is connected with a supporting leg I (2-2), the supporting leg I (2-2) is connected with an upper platform (2-3), the upper platform (2-3) is connected with a speed-losing box (2-4), an inlet port (2-7) is arranged on the upper platform (2-3), the inlet port (2-7) is communicated with the speed-losing box (2-4), a baffle (2-8) is connected with a cutting supporting table (2-9), the cutting supporting table (2-9) is hinged with a hinged arm (2-10), and the hinged arm (2-10) is hinged with a hinged arm I (2-11), the articulated arm I (2-11) is articulated with the upper platform (2-3), the articulated arm I (2-11) is articulated with an articulated joint (2-12), the articulated joint (2-12) is connected with a hydraulic cylinder (2-13), the hydraulic cylinder (2-13) is articulated with a hydraulic cylinder support (2-14), the hydraulic cylinder support (2-14) is connected with the upper platform (2-3), a U-shaped pipe (2-15) is communicated with a drainage channel (2-27) arranged on the upper platform (2-3), the U-shaped pipe (2-15) is connected with the upper platform (2-3), the upper platform (2-3) is connected with a motor base (2-16), the motor base (2-16) is connected with a recovery motor (2-17), the recovery motor (2-17) is connected with a transmission belt pulley (2-18), the transmission belt pulleys (2-18) are in friction connection with the belt II (2-5), the belt II (2-5) is in friction connection with the belt pulley II (2-6), the air box I (2-19) is connected with the upper platform (2-3), the air box I (2-19) is communicated with the stall box (2-4) through a step connecting pipe (2-21), an outlet (2-20) is arranged on the stall box (2-4), the stall scraping wheel (2-22) is connected with the belt pulley II (2-6), the stall scraping wheel (2-22) is in rotation connection with the stall box (2-4), the drainage belt shaft air wheel (2-23) is in rotation connection with the air box I (2-19), the drainage belt shaft air wheel (2-23) is connected with the transmission belt pulleys (2-18), the inner slide rod (2-24) is connected with the upper platform (2-3), the inner sliding rods (2-24) are arranged in sliding grooves I (2-25), the sliding grooves I (2-25) are arranged on an upper platform (2-3), return springs (2-26) are sleeved on the inner sliding rods (2-24), two ends of each return spring (2-26) are respectively connected to the upper platform (2-3) and a cutting support platform (2-9), the cutting support platforms (2-9) are in sliding connection with the inner sliding rods (2-24), the cutting support platforms (2-9) are in sliding connection with the sliding grooves I (2-25), and supporting legs (1-1), connecting boxes (1-15) and supporting seats (1-18) are all wedge blocks of the upper platform (2-3).

4. The smart cut manufacturing device of claim 1, wherein: the vibration packing mechanism (3) comprises a discharge pipe (3-1), a side pressing seat (3-2), a limit square column (3-3), a bidirectional screw rod (3-4), a servo motor (3-5), a collecting hopper (3-6), a limit connecting plate (3-7), a floating frame with holes (3-8), a sliding column (3-9), a self-vibration spring (3-10) and a lower support frame (3-11), the discharge pipe (3-1) is connected and communicated with the collecting hopper (3-6), the side pressing seat (3-2) is in sliding connection with the limit square column (3-3), the limit square column (3-3) is connected with the collecting hopper (3-6), the bidirectional screw rod (3-4) is in threaded connection with the side pressing seat (3-2), the bidirectional screw rod (3-4) is in rotating connection with the collecting hopper (3-6), the servo motor (3-5) is connected with the collecting hopper (3-6), the servo motor (3-5) is connected with the bidirectional screw rod (3-4), the collecting hopper (3-6) is connected with the porous floating frame (3-8), the porous floating frame (3-8) is connected with the sliding column (3-9) in a sliding mode, the sliding column (3-9) is connected with the limiting connecting plate (3-7), the sliding column (3-9) is connected with the lower supporting frame (3-11), the lower supporting frame (3-11) is connected with the base (2-1), the self-vibrating spring (3-10) is sleeved on the sliding column (3-9), and two ends of the self-vibrating spring (3-10) are connected to the porous floating frame (3-8) and the lower supporting frame (3-11) respectively.

5. The smart cut manufacturing device of claim 4, wherein: the collecting hopper (3-6) is made of high manganese steel.

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