CN112025847A

CN112025847A - Intelligence sword saw cutting equipment

Info

Publication number: CN112025847A
Application number: CN202011033405.7A
Authority: CN
Inventors: 陈柳娜
Original assignee: Guangzhou Muyue Information Technology Co ltd
Current assignee: Guangzhou Muyue Information Technology Co ltd
Priority date: 2020-09-27
Filing date: 2020-09-27
Publication date: 2020-12-04

Abstract

The invention relates to the field of intelligent manufacturing, in particular to an intelligent knife saw cutting device, which is used for cutting wood, wherein the wood is subjected to cutting treatment during wood processing, the traditional device cannot cut wood sections with the same length in a large batch each time, the length of the produced wood sections cannot be adjusted or the error is too large, so that the length of each cut section is inconsistent, the device solves the problems by arranging the wood in a feeding combination body, reciprocating and rotating a saw blade to cut the wood in the feeding combination body at two sides, when the saw blade is used for cutting, the friction transmission of the feeding combination body fails, the feeding combination body does not feed the wood, so that the straight cutting of the wood is ensured, the reciprocating motion of the saw blade to cut the wood at two sides ensures that the length of each cut section is consistent, when the wood is difficult to cut, the rotating speed of the saw blade is reduced, the advancing speed of the saw blade is automatically reduced, the saw blade is, the sawdust blowing assembly can blow away sawdust generated by cutting.

Description

Intelligence sword saw cutting equipment

Technical Field

The invention relates to the field of intelligent manufacturing, in particular to intelligent knife saw cutting equipment.

Background

The wood processing needs to be subjected to cutting treatment, the traditional equipment cannot cut wood sections with the same length in a large batch at each time, the length of the produced wood sections cannot be adjusted, or the error is too large, so that the cutting length is inconsistent at each time.

Disclosure of Invention

The invention aims to provide intelligent knife saw cutting equipment which can cut wood sections with the same length in a large scale, can adjust the length of the produced wood sections with small error and can automatically clean wood chips on a worktable.

The purpose of the invention is realized by the following technical scheme:

the utility model provides an intelligence sword saw cutting equipment, includes cutting assembly, pay-off assembly and blows the bits assembly, pay-off assembly, blow the bits assembly and all be connected with the cutting assembly.

As a further optimization of the technical scheme, the cutting assembly comprises a cutting transmission box, a servo motor I, a motor support, a motor slide rail, a toothed bar, a servo motor I shaft, a walking gear, a transmission support, a saw blade shaft, a transmission support slide rail, a saw blade, a belt wheel I, a belt and a belt wheel II, wherein the motor slide rail and the toothed bar are connected with the cutting transmission box, the servo motor I is connected with the motor support, the motor support is connected with the motor slide rail and the toothed bar in a sliding manner, the servo motor I shaft is connected with the servo motor I shaft, the servo motor I shaft is connected with the walking gear, the walking gear is connected with the toothed bar in a meshing manner, the servo motor I shaft is connected with the transmission support in a rotating manner, the transmission support is connected with the motor support, the transmission support is connected with the transmission support slide rail in a sliding manner, the transmission support slide rail is connected with, the saw bit axle is connected with the saw bit, and I axle of servo motor is connected with band pulley I, and band pulley I is connected with band pulley II through the belt, and band pulley II is connected with the saw bit axle.

As a further optimization of the technical scheme, the feeding assembly comprises a limiting cage I, a limiting cage II, supporting rods, connecting blocks, sliding toothed rods, baffles, a feeding transmission case, supporting legs, a servo motor II shaft, friction wheel chutes, rocking handles, threaded shafts, threaded limiting sleeves, friction wheels, fluted discs, fluted disc shafts, lower gears, gear shafts and upper gears, wherein the two limiting cages I and the two limiting cages II are connected with a cutting transmission case respectively, the two limiting cages II are connected with two groups of supporting rods respectively, the two groups of supporting rods are connected with two connecting blocks respectively, the two connecting blocks are connected with the two sliding toothed rods respectively in a sliding manner, the two sliding toothed rods are connected with the two baffles respectively, the two connecting blocks are connected with the feeding transmission case, the feeding transmission case is connected with the supporting legs, the servo motor II is connected with the feeding transmission case, the servo motor II is connected with the servo motor II shaft, the second shaft of the servo motor is rotationally connected with the feeding transmission box, the sliding chute of the friction wheel is positioned on the second shaft of the servo motor, the rocking handle is connected with the threaded shaft, the threaded shaft is rotationally connected with the feeding transmission box, the threaded shaft is in threaded connection with the threaded stop collar, the threaded stop collar is in sliding connection with the second shaft of the servo motor, the friction wheel is in contact with the threaded stop collar, the friction wheel is in sliding connection with the sliding chute of the friction wheel, the friction wheel is in close contact with the fluted disc, the fluted disc is connected with the fluted disc shaft, the fluted disc shaft is rotationally connected with the feeding transmission box, the fluted disc is in meshed connection with the two lower gears, the two lower gears are respectively connected with the two gear shafts, the two gear shafts are rotationally connected with the feeding transmission box, the two gear shafts are respectively connected with the two upper.

As a further optimization of the technical scheme, the scrap blowing assembly comprises a scrap blowing support I, a scrap blowing upper support, a scrap blowing support II, a rotating frame shaft, a rotating frame, a double-end motor, a motor support shaft, a motor shaft I, fan blades, a motor shaft II, a gear I, a gear II, a gear III, a gear IV, a motor shaft II support and a connecting shaft, wherein the two scrap blowing supports I are connected with a cutting transmission box, the two scrap blowing supports I are connected with the scrap blowing upper support, the scrap blowing upper support is connected with the two scrap blowing supports II, the two scrap blowing supports II are respectively in rotating connection with the two rotating frame shafts, the two rotating frame shafts are respectively connected with the rotating frame, the double-end motor is connected with the two motor support shafts, the two motor support shafts are respectively in rotating connection with the rotating frame, the two ends of the double-end motor are respectively connected with the motor shaft I and the motor shaft II, the motor shaft I is connected with, gear I is connected with II meshing of gear, and gear II is connected with II axles of gear, and II axles of gear rotate with double-end motor to be connected, and II axles of gear are connected with gear III, and gear III meshes with gear IV to be connected, and gear IV is connected with motor shaft II, and motor shaft II rotates with II leg joint on the motor shaft, and II supports on the motor shaft are connected with the connecting axle, and the connecting axle rotates with the blowing bits upper bracket to be connected.

The intelligent knife saw cutting equipment has the beneficial effects that:

drawings

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

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

FIG. 2 is a first schematic structural diagram of the present invention;

FIG. 3 is a second schematic structural view of the present invention;

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

FIG. 5 is a first schematic structural diagram of the present invention;

FIG. 6 is a structural cross-sectional view of the present invention;

FIG. 7 is a first schematic structural diagram of the present invention;

FIG. 8 is a second schematic structural view of the present invention;

FIG. 9 is a third schematic structural view of the present invention;

FIG. 10 is a fourth schematic structural view of the present invention;

FIG. 11 is a first schematic structural diagram of the present invention;

FIG. 12 is a second schematic structural diagram of the present invention.

In the figure: a cutting assembly 1; cutting the transmission case 1-1; a servo motor I1-2; 1-3 of a motor bracket; 1-4 of a motor slide rail; 1-5 of a toothed bar; 1-6 shafts of a servo motor I; 1-7 parts of a traveling gear; 1-8 parts of a transmission bracket; saw blade shafts 1-9; 1-10 parts of a transmission bracket slide rail; 1-11 parts of saw blade; 1-12 belt wheels; 1-13 of a belt; belt wheels II 1-14; a feeding assembly 2; a limiting cage I2-1; a limiting cage II 2-2; 2-3 of a support rod; 2-4 of a connecting block; 2-5 of a sliding rack bar; 2-6 parts of a baffle plate; 2-7 parts of a feeding transmission case; 2-8 parts of supporting legs; 2-9 of a servo motor; 2-10 of a servo motor II shaft; 2-11 friction wheel chutes; 2-12 of a rocking handle; 2-13 of a threaded shaft; 2-14 parts of a threaded stop collar; 2-15 parts of friction wheel; 2-16 of a fluted disc; 2-17 of a fluted disc shaft; lower gears 2-18; gear shafts 2-19; 2-20 parts of upper gear; a scrap blowing assembly 3; the scrap blowing support I3-1; blowing scraps to the upper bracket 3-2; a scrap blowing bracket II 3-3; 3-4 of a rotating frame shaft; rotating the frame 3-5; 3-6 parts of a double-end motor; a motor supporting shaft 3-7; a motor shaft I is 3-8; 3-9 parts of fan blades; a motor shaft II is 3-10; 3-11 parts of a gear I; 3-12 parts of a gear II; 3-13 of a gear II shaft; gears III 3 to 14; 3-15 parts of a gear IV; 3-16 parts of a motor shaft II bracket; connecting the shafts 3-17.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

referring to fig. 1-12, in the present embodiment, an intelligent cutting device for a knife saw includes a cutting assembly 1, a feeding assembly 2, and a scrap blowing assembly 3, where the feeding assembly 2 and the scrap blowing assembly 3 are both connected to the cutting assembly 1.

The second embodiment is as follows:

referring to fig. 1-12, the present embodiment will be further described, in which the cutting assembly 1 includes a cutting transmission case 1-1, a servo motor i 1-2, a motor support 1-3, a motor slide rail 1-4, a rack bar 1-5, a servo motor i shaft 1-6, a traveling gear 1-7, a transmission support 1-8, a saw blade shaft 1-9, a transmission support slide rail 1-10, a saw blade 1-11, a belt pulley i 1-12, a belt 1-13 and a belt pulley ii 1-14, the motor slide rail 1-4 and the rack bar 1-5 are connected to the cutting transmission case 1-1, the servo motor i 1-2 is connected to the motor support 1-3, the motor support 1-3 is connected to the motor slide rail 1-4 and the rack bar 1-5 in a sliding manner, the servo motor I1-2 is connected with a servo motor I shaft 1-6, the servo motor I shaft 1-6 is connected with a walking gear 1-7, the walking gear 1-7 is connected with a rack bar 1-5 in a meshing way, the servo motor I shaft 1-6 is rotationally connected with a transmission bracket 1-8, the transmission bracket 1-8 is connected with a motor bracket 1-3, the transmission bracket 1-8 is slidably connected with a transmission bracket slide rail 1-10, the transmission bracket slide rail 1-10 is connected with a cutting transmission box 1-1, a saw blade shaft 1-9 is rotationally connected with a transmission bracket 1-8, the saw blade shaft 1-9 is connected with a saw blade 1-11, the servo motor I shaft 1-6 is connected with a belt wheel I1-12, the belt wheel I1-12 is connected with a belt wheel II 1-14 through a belt 1-13, the belt wheels II 1-14 are connected with saw blade shafts 1-9.

The third concrete implementation mode:

referring to the embodiment shown in fig. 1-12, the first embodiment is further described, and the feeding assembly 2 includes a limiting cage i 2-1, a limiting cage ii 2-2, a support rod 2-3, a connecting block 2-4, a sliding toothed bar 2-5, a baffle plate 2-6, a feeding transmission box 2-7, a support leg 2-8, a servo motor ii 2-9, a servo motor ii shaft 2-10, a friction wheel chute 2-11, a rocking handle 2-12, a threaded shaft 2-13, a threaded limiting sleeve 2-14, a friction wheel 2-15, a fluted disc 2-16, a fluted disc shaft 2-17, a lower gear 2-18, a gear shaft 2-19 and an upper gear 2-20, wherein the two limiting cages i 2-1 and the two limiting cages ii 2-2 are connected to a cutting transmission box 1-1, two limit cages II 2-2 are respectively connected with two groups of support rods 2-3, two groups of support rods 2-3 are respectively connected with two connecting blocks 2-4, two connecting blocks 2-4 are respectively connected with two sliding gear rods 2-5 in a sliding manner, two sliding gear rods 2-5 are respectively connected with two baffles 2-6, two connecting blocks 2-4 are both connected with a feeding transmission box 2-7, the feeding transmission box 2-7 is connected with a supporting leg 2-8, a servo motor II 2-9 is connected with the feeding transmission box 2-7, a servo motor II 2-9 is connected with a servo motor II shaft 2-10, the servo motor II shaft 2-10 is rotatably connected with the feeding transmission box 2-7, a friction wheel chute 2-11 is positioned on the servo motor II shaft 2-10, the rocking handle 2-12 is connected with a threaded shaft 2-13, the threaded shaft 2-13 is rotationally connected with a feeding transmission box 2-7, the threaded shaft 2-13 is in threaded connection with a threaded limit sleeve 2-14, the threaded limit sleeve 2-14 is in sliding connection with a servo motor II shaft 2-10, a friction wheel 2-15 is in contact with the threaded limit sleeve 2-14, the friction wheel 2-15 is in sliding connection with a friction wheel chute 2-11, the friction wheel 2-15 is in tight contact with a fluted disc 2-16, the fluted disc 2-16 is connected with a fluted disc shaft 2-17, the fluted disc shaft 2-17 is rotationally connected with the feeding transmission box 2-7, the fluted disc 2-16 is in meshed connection with two lower gears 2-18, the two lower gears 2-18 are respectively connected with two gear shafts 2-19, the two gear shafts 2-19 are rotatably connected with the feeding transmission box 2-7, the two gear shafts 2-19 are respectively connected with the two upper gears 2-20, and the two upper gears 2-20 are respectively meshed and connected with the two sliding gear rods 2-5.

The fourth concrete implementation mode:

referring to the embodiment shown in fig. 1-12, the scrap blowing assembly 3 includes a scrap blowing support i 3-1, a scrap blowing upper support 3-2, a scrap blowing support ii 3-3, a rotating frame shaft 3-4, a rotating frame 3-5, a double-head motor 3-6, a motor support shaft 3-7, a motor shaft i 3-8, a fan blade 3-9, a motor shaft ii 3-10, a gear i 3-11, a gear ii 3-12, a gear ii shaft 3-13, a gear iii 3-14, a gear iv 3-15, a motor shaft ii support 3-16 and a connecting shaft 3-17, wherein two scrap blowing supports i 3-1 are connected to a cutting transmission case 1-1, two scrap blowing supports i 3-1 are connected to the scrap blowing upper support 3-2, the scrap blowing upper bracket 3-2 is connected with two scrap blowing brackets II 3-3, the two scrap blowing brackets II 3-3 are respectively rotatably connected with two rotating frame shafts 3-4, the two rotating frame shafts 3-4 are respectively connected with a rotating frame 3-5, the double-head motor 3-6 is connected with two motor supporting shafts 3-7, the two motor supporting shafts 3-7 are respectively rotatably connected with the rotating frame 3-5, both ends of the double-head motor 3-6 are respectively connected with a motor shaft I3-8 and a motor shaft II 3-10, the motor shaft I3-8 is connected with a fan blade 3-9, the motor shaft II 3-10 is connected with a gear I3-11, the gear I3-11 is meshed with a gear II 3-12, the gear II 3-12 is connected with a gear II shaft 3-13, the gear II shaft 3-13 is rotatably connected with the double-head motor 3-6, the gear II shaft 3-13 is connected with the gear III 3-14, the gear III 3-14 is meshed with the gear IV 3-15, the gear IV 3-15 is connected with the motor shaft II 3-10, the motor shaft II 3-10 is rotatably connected with the motor shaft II bracket 3-16, the motor shaft II bracket 3-16 is connected with the connecting shaft 3-17, and the connecting shaft 3-17 is rotatably connected with the scrap blowing upper bracket 3-2.

The invention relates to an intelligent knife saw cutting device, which has the working principle that: putting wood on a support rod 2-3, enabling one end of the wood to be in contact with a baffle 2-6, starting a servo motor II 2-9, enabling the servo motor II 2-9 to drive a servo motor II shaft 2-10 to rotate, enabling the servo motor II shaft 2-10 to drive a friction wheel 2-15 to rotate through a friction wheel sliding groove 2-11, enabling the friction wheel 2-15 to be in close contact with a fluted disc 2-16, enabling the friction wheel 2-15 to drive the fluted disc 2-16 to rotate, enabling the fluted disc 2-16 to drive two lower gears 2-18 to rotate, enabling the two lower gears 2-18 to drive two gear shafts 2-19 to rotate, enabling the two gear shafts 2-19 to drive two upper gears 2-20 to rotate, enabling the two gear shafts 2-19 to drive two sliding gear rods 2-5 to respectively slide in two connecting blocks, two sliding gear rods 2-5 respectively drive two baffle plates 2-6 to move, the two baffle plates 2-6 push wood to slide towards a limiting cage II 2-2 and a limiting cage I2-1, a servo motor I1-2 is started, a servo motor I1-2 drives a servo motor I shaft 1-6 to rotate, the servo motor I shaft 1-6 drives a walking gear 1-7 to rotate, the walking gear 1-7 rolls on the gear rods 1-5, the walking gear 1-7 drives a motor bracket 1-3 to slide on a motor slide rail 1-4 and the gear rods 1-5 through the servo motor I shaft 1-6 and the servo motor I1-2, the revolution number of the servo motor I1-2 is preset, so that the servo motor I1-2 starts to rotate reversely when sliding to two ends of the motor slide rail 1-4, thus, the servo motor I1-2 drives the motor bracket 1-3 to slide back and forth at a constant speed, the motor bracket 1-3 drives the transmission bracket 1-8 to slide back and forth, the transmission bracket 1-8 drives the saw blade shaft 1-9 to slide back and forth, the saw blade shaft 1-9 drives the saw blade 1-11 to slide back and forth in the cutting transmission box 1-1, the servo motor I shaft 1-6 drives the belt wheel I1-12 to rotate, the belt wheel I1-12 drives the belt wheel II 1-14 to rotate through the belt 1-13, the belt wheel II 1-14 drives the saw blade shaft 1-9 to rotate, the saw blade shaft 1-9 drives the saw blade 1-11 to rotate, the saw blade 1-11 rotates at a high speed while sliding back and forth in the cutting transmission box 1-1, when the saw blade 1-11 contacts with wood and cuts, the baffle 2-6 can not push the wood to move forward continuously, the friction transmission failure of the friction wheel 2-15 can not drive the fluted disc 2-16 to rotate, the wood on both sides stops advancing, the saw blade 1-11 cuts the wood and moves reversely to cut another group of wood, thus the saw blade 1-11 cuts the wood into wood sections with consistent length in a reciprocating way, when the wood is solid, the cutting speed of the saw blade 1-11 is slowed, the rotating speed of the shaft 1-6 of the servo motor I drives the walking gear 1-7 to be slowed, the sliding speed of the servo motor I1-2 is slowed, the sliding speed of the saw blade 1-11 is slowed, the saw blade 1-11 can not collapse because of too fast movement due to too low rotating speed, the saw blade is protected, when the cutting length of the wood sections needs to be adjusted, the rocking handle 2-12 drives the threaded shaft, the threaded shaft 2-13 drives the threaded limiting sleeve 2-14 to slide on the shaft 2-10 of the servo motor II, the threaded limiting sleeve 2-14 drives the friction wheel 2-15 to slide in the friction wheel sliding groove 2-11, the transmission ratio of the friction wheel 2-15 and the fluted disc 2-16 is changed by changing the contact position of the friction wheel 2-15 and the fluted disc 2-16, so that the speed of the baffle plate 2-6 for pushing wood is changed, the cutting length of each wood section is changed, wood chips are accumulated beside a saw blade 1-11 to influence cutting, the wood chips can leak into the cutting transmission box 1-1 to influence transmission, the double-head motor 3-6 is started, the double-head motor 3-6 drives the motor shaft I3-8 to rotate, and the motor shaft I3-8 drives the fan blade 3-9 to blow air in a direction of 30 degrees in the vertical direction, the double-head motor 3-6 drives the motor shaft II 3-10 to rotate, the motor shaft II 3-10 drives the gear I3-11 to rotate, the gear I3-11 drives the gear II 3-12 to rotate at a reduced speed, the gear II 3-12 drives the gear II shaft 3-13 to rotate, the gear II shaft 3-13 drives the gear III 3-14 to rotate, the gear III 3-14 rolls on the surface of the gear IV 3-15, the gear III 3-14 drives the double-head motor 3-6 to rotate obliquely through the gear II shaft 3-13, the double-head motor 3-6 drives the motor shaft II 3-10 to rotate obliquely, the motor shaft II 3-10 drives the connecting shaft 3-17 to rotate through the motor shaft II bracket 3-16, the motor shaft I3-8 drives the fan blade 3-9 to rotate obliquely through the motor shaft I3-, the fan blades rotate and blow air to 30-degree direction circular motion in the vertical direction at the same time, so that sawdust on the cutting assembly 1 is blown away, and normal cutting is guaranteed.

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

1. The utility model provides an intelligence sword saw cutting equipment, includes cutting assembly (1), pay-off assembly (2) and blows bits assembly (3), its characterized in that: the feeding assembly (2) and the scrap blowing assembly (3) are connected with the cutting assembly (1).

2. The smart saber saw cutting apparatus of claim 1, wherein: the cutting assembly (1) comprises a cutting transmission box (1-1), a servo motor I (1-2), a motor support (1-3), a motor sliding rail (1-4), a toothed bar (1-5), a servo motor I shaft (1-6), a walking gear (1-7), a transmission support (1-8), a saw blade shaft (1-9), a transmission support sliding rail (1-10), a saw blade (1-11), a belt wheel I (1-12), a belt (1-13) and a belt wheel II (1-14), the motor sliding rail (1-4) and the toothed bar (1-5) are connected with the cutting transmission box (1-1), the servo motor I (1-2) is connected with the motor support (1-3), and the motor support (1-3) is connected with the motor sliding rail (1-4), The gear rod (1-5) is connected in a sliding way, the servo motor I (1-2) is connected with the servo motor I shaft (1-6), the servo motor I shaft (1-6) is connected with the walking gear (1-7), the walking gear (1-7) is meshed with the gear rod (1-5), the servo motor I shaft (1-6) is rotatably connected with the transmission bracket (1-8), the transmission bracket (1-8) is connected with the motor bracket (1-3), the transmission bracket (1-8) is slidably connected with the transmission bracket sliding rail (1-10), the transmission bracket sliding rail (1-10) is connected with the cutting transmission box (1-1), the saw blade shaft (1-9) is rotatably connected with the transmission bracket (1-8), the saw blade shaft (1-9) is connected with the saw blade (1-11), a servo motor I shaft (1-6) is connected with a belt wheel I (1-12), the belt wheel I (1-12) is connected with a belt wheel II (1-14) through a belt (1-13), and the belt wheel II (1-14) is connected with a saw blade shaft (1-9).

3. The smart saber saw cutting apparatus of claim 1, wherein: the feeding assembly (2) comprises a limiting cage I (2-1), a limiting cage II (2-2), supporting rods (2-3), connecting blocks (2-4), sliding gear rods (2-5), baffles (2-6), a feeding transmission box (2-7), supporting legs (2-8), a servo motor II (2-9), a servo motor II shaft (2-10), friction wheel chutes (2-11), rocking handles (2-12), threaded shafts (2-13), threaded limiting sleeves (2-14), friction wheels (2-15), a fluted disc (2-16), a fluted disc shaft (2-17), lower gears (2-18), gear shafts (2-19) and upper gears (2-20), wherein the two limiting cages I (2-1) and the two limiting cages II (2-2) are connected with a cutting transmission box (1-1), two limiting cages II (2-2) are respectively connected with two groups of supporting rods (2-3), two groups of supporting rods (2-3) are respectively connected with two connecting blocks (2-4), two connecting blocks (2-4) are respectively connected with two sliding toothed bars (2-5) in a sliding manner, two sliding toothed bars (2-5) are respectively connected with two baffles (2-6), two connecting blocks (2-4) are respectively connected with a feeding transmission box (2-7), the feeding transmission box (2-7) is connected with supporting legs (2-8), a servo motor II (2-9) is connected with the feeding transmission box (2-7), a servo motor II (2-9) is connected with a servo motor II shaft (2-10), and the servo motor II shaft (2-10) is rotationally connected with the feeding transmission box (2-7), the friction wheel sliding groove (2-11) is positioned on the servo motor II shaft (2-10), the rocking handle (2-12) is connected with the threaded shaft (2-13), the threaded shaft (2-13) is rotationally connected with the feeding transmission box (2-7), the threaded shaft (2-13) is in threaded connection with the threaded limiting sleeve (2-14), the threaded limiting sleeve (2-14) is in sliding connection with the servo motor II shaft (2-10), the friction wheel (2-15) is in contact with the threaded limiting sleeve (2-14), the friction wheel (2-15) is in sliding connection with the friction wheel sliding groove (2-11), the friction wheel (2-15) is in close contact with the fluted disc (2-16), the fluted disc (2-16) is connected with the fluted disc shaft (2-17), the fluted disc shaft (2-17) is rotationally connected with the feeding transmission box (2-7), the fluted disc (2-16) is meshed with the two lower gears (2-18), the two lower gears (2-18) are respectively connected with the two gear shafts (2-19), the two gear shafts (2-19) are both rotationally connected with the feeding transmission box (2-7), the two gear shafts (2-19) are respectively connected with the two upper gears (2-20), and the two upper gears (2-20) are respectively meshed with the two sliding gear rods (2-5).

4. The smart saber saw cutting apparatus of claim 1, wherein: the scrap blowing assembly (3) comprises a scrap blowing support I (3-1), a scrap blowing upper support (3-2), a scrap blowing support II (3-3), a rotating frame shaft (3-4), a rotating frame (3-5), a double-end motor (3-6), a motor support shaft (3-7), a motor shaft I (3-8), fan blades (3-9), a motor shaft II (3-10), gears I (3-11), gears II (3-12), gears II (3-13), gears III (3-14), gears IV (3-15), motor shaft II supports (3-16) and connecting shafts (3-17), wherein the two scrap blowing supports I (3-1) are connected with a cutting transmission case (1-1), the two scrap blowing supports I (3-1) are connected with the scrap blowing upper support (3-2), the scrap blowing upper support (3-2) is connected with two scrap blowing supports II (3-3), the two scrap blowing supports II (3-3) are respectively rotatably connected with two rotating frame shafts (3-4), the two rotating frame shafts (3-4) are respectively connected with the rotating frame (3-5), the double-head motor (3-6) is connected with two motor support shafts (3-7), the two motor support shafts (3-7) are respectively rotatably connected with the rotating frame (3-5), two ends of the double-head motor (3-6) are respectively connected with a motor shaft I (3-8) and a motor shaft II (3-10), the motor shaft I (3-8) is connected with a fan blade (3-9), the motor shaft II (3-10) is connected with a gear I (3-11), the gear I (3-11) is meshed with a gear II (3-12), the gear II (3-12) is connected with a gear II shaft (3-13), the gear II shaft (3-13) is rotationally connected with the double-head motor (3-6), the gear II shaft (3-13) is connected with the gear III (3-14), the gear III (3-14) is meshed with the gear IV (3-15), the gear IV (3-15) is connected with the motor shaft II (3-10), the motor shaft II (3-10) is rotationally connected with a motor shaft II bracket (3-16), the motor shaft II bracket (3-16) is connected with a connecting shaft (3-17), and the connecting shaft (3-17) is rotationally connected with the scrap blowing upper bracket (3-2).