CN113275651A - Automatic blanking equipment of sawing machine - Google Patents

Abstract

The invention relates to the field of bar cutting machinery, in particular to automatic blanking equipment of a sawing machine, wherein bars are loaded and conveyed through a sawing machine component, the cutting component is used for cutting the bars, a rotating rod is driven through a first transmission shaft, a first sliding block drives a saw blade to slide left and right, a fourth transmission belt is matched with a first transmission shaft and a first half gear shaft, a first half gear shaft is meshed with a toothed chain, a second transmission block drives the saw blade to adjust the position, the transmission component is used for transmitting after the bars are cut, so that the bars are cut again, through the sliding of a trigger block, a first clutch is meshed with a second clutch, a worm is driven to rotate, and the worm is meshed with a turbine, so that the transmission belt is driven to continue to convey, the operability of the workers is reduced and it is agreed that multiple sawing machines can be operated to increase production.

Description

Automatic blanking equipment of sawing machine

Technical Field

The invention relates to the field of bar cutting machinery, in particular to automatic blanking equipment of a sawing machine.

Background

When a factory cuts the bar stock, the automatic operation cannot be carried out, and the bar stock needs to be moved again after each cutting, and then the cutting is carried out.

Disclosure of Invention

The invention aims to provide automatic blanking equipment of a sawing machine, which can load and convey a bar through a sawing machine component, wherein the cutting component is used for cutting the bar, and the transmission component is used for transmitting the bar after the bar is cut so as to cut again.

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

the automatic blanking equipment for the sawing machine comprises a sawing machine component, a cutting component and a transmission component, wherein the sawing machine component is connected with the cutting component, the sawing machine component is connected with the transmission component, and the cutting component is connected with the transmission component.

As a further optimization of the technical scheme, the automatic blanking device of the sawing machine comprises a bar material, a bar material support, a fixed frame, a turbine, a roller, a conveyor belt, a first transmission belt, a semi-bevel gear shaft, a bevel gear shaft support, a first bevel gear, a second bevel gear, a cross rod, a bevel gear sleeve, a screw rod, a cushion block, a first fixed block, a first spring and a through hole, wherein the bar material is in sliding connection with the bar material support, the bar material is in sliding connection with the fixed frame, the turbine is fixedly connected with the roller, the roller is in rotating connection with the fixed frame, the roller is in matching connection with the conveyor belt, the conveyor belt is in sliding connection with the bar material, the first transmission belt is in matching connection with the roller, the first transmission belt is in matching connection with the semi-bevel gear shaft, the semi-bevel gear shaft is in rotating connection with the bevel gear shaft support, the bevel gear shaft support is fixedly connected with the fixed frame, the first bevel gear is in meshing connection with the semi-bevel gear shaft, the first bevel gear is in sliding connection with the cross rod, the second bevel gear is meshed with the semi-bevel gear shaft and is connected with the cross rod in a sliding mode, the bevel gear sleeve is rotationally connected with the first bevel gear, the bevel gear sleeve is rotationally connected with the second bevel gear, the screw rod is fixedly connected with the cross rod and is in threaded connection with the fixed rack, the screw rod is in contact with the cushion block, the cushion block is fixedly connected with the first fixed block, one end of the first spring is in contact with the first fixed block, the other end of the first spring is in contact with the fixed rack, and the through hole is formed in the fixed rack.

As a further optimization of the technical scheme, the invention relates to automatic blanking equipment of a sawing machine, wherein a cutting component comprises a motor, a transmission belt II, a transmission belt III, a transmission shaft I, a transmission shaft support I, a rotating rod, a sliding bearing, a slide block I, a slide block support I, a transmission belt IV, a half gear shaft I, a toothed chain, a half gear shaft II, a transmission belt V, a half gear shaft support, a slide block II, a fixed block II, a convex block, a spring II, a sliding chute, a groove, a saw blade, a slide block III, a spring III and a slide block support II, wherein the motor is fixedly connected with the fixed rack, the motor is in matched connection with the transmission belt II, the motor is in matched connection with the transmission belt III, the transmission belt III is in matched connection with the transmission shaft I, the transmission shaft I is rotatably connected with the transmission shaft support I, the transmission shaft support I is fixedly connected with the fixed rack, the rotating rod is fixedly connected with the transmission shaft I, and the rotating rod is slidably connected with the sliding bearing, the sliding bearing is connected with one sliding block in a rotating mode, the first sliding block is connected with the first sliding block support in a sliding mode, the first sliding block support is fixedly connected with the fixed rack, the fourth transmission belt is connected with the first transmission shaft in a matching mode, the fourth transmission belt is connected with the first half gear shaft in a matching mode, a toothed chain is connected with the first half gear shaft in a meshing mode, the toothed chain is connected with the second half gear shaft in a meshing mode, the fifth transmission belt is connected with the first half gear shaft in a matching mode, the fifth transmission belt is connected with the second half gear shaft in a matching mode, the first half gear shaft support is connected with the first half gear shaft in a rotating mode, the second half gear shaft support is connected with the second half gear shaft in a rotating mode, the second half gear shaft support is fixedly connected with the fixed rack, the second sliding block is fixedly connected with the saw blade, the second fixed block is connected with the second sliding block, the second, the saw blade is in contact with the bar, the saw blade is in sliding connection with the third sliding block, the third sliding block is in sliding connection with the second sliding block support, one end of the third spring is in contact with the third sliding block, the other end of the third spring is in contact with the second sliding block support, and the second sliding block support is fixedly connected with the fixed rack.

As a further optimization of the technical scheme, the invention relates to automatic blanking equipment of a sawing machine, which comprises a hinged column, a receiving plate, a spring IV, a trigger block, a clutch I, a clutch II, a transmission shaft bracket II, a transmission belt VI, a worm and a worm bracket, wherein the hinged column is fixedly connected with a fixed frame, the receiving plate is rotatably connected with the hinged column, one end of the spring IV is contacted with the receiving plate, the other end of the spring IV is contacted with the fixed frame, the trigger block is in sliding connection with a through hole, the trigger block is fixedly connected with the clutch I, the clutch I is in meshing connection with the clutch II, the clutch II is fixedly connected with the transmission shaft II, the transmission shaft II is rotatably connected with the transmission shaft bracket II, the transmission shaft bracket II is fixedly connected with the fixed frame, the transmission belt VI is in matching connection with the trigger block, the transmission belt VI is in matching connection with the worm, and the worm is rotatably connected with the worm bracket, the worm support is fixedly connected with the fixed frame.

The automatic blanking equipment of the sawing machine has the beneficial effects that:

the invention relates to automatic blanking equipment of a sawing machine, wherein a sawing machine component drives a roller to rotate through a turbine so as to drive a half-bevel gear shaft to drive a bevel gear, a lead screw is in threaded connection to drive a fixed block to fix a bar, a cutting component drives a rotating rod through a first transmission shaft so as to drive a first sliding block to drive a saw blade to slide left and right, a fourth transmission belt is matched with a first transmission shaft and a first half-gear shaft, the first half-gear shaft is meshed with a toothed chain, a second transmission block drives the saw blade to adjust the position, the transmission component drives the first clutch to be meshed with a second clutch through the sliding of a trigger block so as to drive a worm to rotate, the worm is meshed with the turbine and then drives the transmission belt to continue to transmit, the automatic blanking equipment of the sawing machine is characterized in that after the bar is cut, the transmission belt is driven to transmit through the triggering after the bar is cut, so that the cutting can be continued, and the operability of workers is reduced, it was agreed that multiple sawing machines could also be operated to increase throughput.

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 view of the saw assembly of the present invention;

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

FIG. 4 is a first schematic view of the cutting assembly of the present invention;

FIG. 5 is a second schematic view of the cutting assembly of the present invention;

FIG. 6 is a third schematic view of the cutting assembly of the present invention;

FIG. 7 is a fourth schematic structural view of the cutting assembly of the present invention;

FIG. 8 is a fifth schematic view of the cutting assembly of the present invention;

FIG. 9 is a sixth schematic view of the cutting assembly of the present invention;

fig. 10 is a schematic view of the transmission assembly of the present invention.

In the figure: a sawing machine assembly 1; 1-1 part of bar stock; 1-2 parts of a bar support; 1-3 of a fixed frame; turbines 1-4; 1-5 of rollers; a conveyor belt 1-6; 1-7 of a first transmission belt; 1-8 parts of a half-cone gear shaft; bevel gear shaft supports 1-9; 1-10 parts of a first bevel gear; 1-11 parts of a bevel gear II; 1-12 of a cross bar; bevel gear sleeves 1-13; 1-14 parts of a lead screw; 1-15 parts of cushion block; 1-16 parts of a first fixed block; 1-17 parts of a first spring; through holes 1-18; a cutting assembly 2; a motor 2-1; a second transmission belt 2-2; a third transmission belt 2-3; a first transmission shaft 2-4; a transmission shaft bracket I2-5; rotating the rods 2-6; sliding bearings 2-7; 2-8 parts of a first sliding block; 2-9 of a first sliding block bracket; driving belt IV 2-10; the first half gear shaft is 2-11; 2-12 of a toothed chain; 2-13 parts of a half gear shaft; a fifth transmission belt 2-14; a half gear shaft support 2-15; 2-16 parts of a second sliding block; 2-17 parts of a second fixed block; 2-18 of bumps; 2-19 parts of a second spring; 2-20 of a chute; 2-21 parts of groove; 2-22 parts of saw blade; 2-23 parts of a sliding block III; 2-24 parts of spring III; 2-25 parts of a second sliding block bracket; a transmission assembly 3; a hinge column 3-1; a receiving plate 3-2; a fourth spring 3-3; 3-4 of a trigger block; 3-5 parts of a first clutch; a second clutch 3-6; 3-7 parts of a second transmission shaft; a second transmission shaft support 3-8; six transmission belts 3-9; 3-10 parts of worm; worm support 3-11.

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; 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:

the embodiment is described below with reference to fig. 1 to 10, and an automatic blanking device for a sawing machine includes a sawing machine assembly 1, a cutting assembly 2, and a transmission assembly 3, where the sawing machine assembly 1 is connected to the cutting assembly 2, the sawing machine assembly 1 is connected to the transmission assembly 3, and the cutting assembly 2 is connected to the transmission assembly 3.

The second embodiment is as follows:

the embodiment is described below by referring to fig. 1-10, and the embodiment further describes the first embodiment, wherein the sawing machine assembly 1 comprises bar stock 1-1, a bar stock support 1-2, a fixed support 1-3, a turbine 1-4, a roller 1-5, a conveyor belt 1-6, a conveyor belt 1-7, a half bevel gear shaft 1-8, a bevel gear shaft support 1-9, a bevel gear 1-10, a bevel gear two 1-11, a cross rod 1-12, a bevel gear sleeve 1-13, a screw 1-14, a cushion block 1-15, a fixed block 1-16, a spring 1-17, a through hole 1-18, a bar stock 1-1 is slidably connected with the bar stock support 1-2, a roller 1-1 is slidably connected with the fixed support 1-3, a turbine 1-4 is fixedly connected with the roller 1-5, the roller 1-5 is rotationally connected with the fixed frame 1-3, the roller 1-5 is in fit connection with the conveyor belt 1-6, the conveyor belt 1-6 is in slide connection with the bar 1-1, the first conveyor belt 1-7 is in fit connection with the roller 1-5, the first conveyor belt 1-7 is in fit connection with the half-cone shaft 1-8, the half-cone shaft 1-8 is in slide connection with the cone shaft bracket 1-9, the cone shaft bracket 1-9 is fixedly connected with the fixed frame 1-3, the first bevel gear 1-10 is in mesh connection with the half-cone shaft 1-8, the first bevel gear 1-10 is in slide connection with the cross rod 1-12, the second bevel gear 1-11 is in mesh connection with the half-cone shaft 1-8, the second bevel gear 1-11 is in slide connection with the cross rod 1-12, and the sleeve 1-13 is in slide connection with the first bevel gear 1-10, the bevel gear sleeve 1-13 is rotatably connected with the bevel gear II 1-11, the screw rod 1-14 is fixedly connected with the cross rod 1-12, the screw rod 1-14 is in threaded connection with the fixed rack 1-3, the screw rod 1-14 is in contact with the cushion block 1-15, the cushion block 1-15 is fixedly connected with the fixed block I1-16, one end of the spring I1-17 is in contact with the fixed block I1-16, the other end of the spring I1-17 is in contact with the fixed rack 1-3, and the through hole 1-18 is formed in the fixed rack 1-3;

when cutting, a bar 1-1 is placed on a bar support 1-2, a fixed rack 1-3 is used for fixing the whole device, a turbine 1-4 is connected with a roller 1-5, the roller 1-5 is driven to rotate after the turbine 1-4 rotates, the roller 1-5 is matched with a conveyor belt 1-6, the conveyor belt 1-6 is driven to convey the bar 1-1, a transmission belt 1-7 is matched with the roller 1-5 and a half-cone-tooth shaft 1-8, when the conveyor belt 1-6 conveys, the roller 1-5 drives the transmission belt 1-7 to transmit, the transmission belt 1-7 drives the half-cone-tooth shaft 1-8 to rotate in a cone-tooth shaft support 1-9, the half-cone-tooth shaft 1-8 is meshed with a cone gear 1-10 after rotating, the first bevel gear 1-10 drives the cross rod 1-12 to rotate forwards, the cross rod 1-12 is connected with the lead screw 1-14, the lead screw 1-14 slides upwards to release the first spring 1-17, the first fixing block 1-16 is disconnected from the bar 1-1, so that the bar 1-1 can be conveyed on the conveyor belt 1-6, the half bevel gear shaft 1-8 rotates for a circle and then is meshed with the second bevel gear 1-11, the second bevel gear 1-11 drives the cross rod 1-12 to rotate backwards to drive the lead screw 1-1 to slide downwards, the lead screw 1-1 drives the cushion block 1-15, the first fixing block 1-16 is compressed by the first spring 1-17 to fix the bar 1-1, and then cutting is ready.

The third concrete implementation mode:

the first embodiment is further described with reference to fig. 1-10, and the cutting assembly 2 includes a motor 2-1, a second driving belt 2-2, a third driving belt 2-3, a first driving shaft 2-4, a first driving shaft support 2-5, a rotating rod 2-6, a sliding bearing 2-7, a first slider 2-8, a first slider support 2-9, a fourth driving belt 2-10, a first half gear shaft 2-11, a toothed chain 2-12, a second half gear shaft 2-13, a fifth driving belt 2-14, a second half gear shaft support 2-15, a second slider 2-16, a second fixed block 2-17, a bump 2-18, a second spring 2-19, a sliding groove 2-20, a groove 2-21, a saw blade 2-22, and a third slider 2-23, A spring III 2-24, a sliding block bracket II 2-25, a motor 2-1 fixedly connected with a fixed rack 1-3, a motor 2-1 cooperatively connected with a transmission belt II 2-2, a motor 2-1 cooperatively connected with a transmission belt III 2-3, a transmission belt III 2-3 cooperatively connected with a transmission shaft I2-4, a transmission shaft I2-4 rotatably connected with a transmission shaft bracket I2-5, a transmission shaft bracket I2-5 fixedly connected with a fixed rack 1-3, a rotating rod 2-6 fixedly connected with a transmission shaft I2-4, a rotating rod 2-6 slidably connected with a sliding bearing 2-7, a sliding bearing 2-7 rotatably connected with a sliding block I2-8, a sliding block I2-8 slidably connected with a sliding block bracket I2-9, a sliding block bracket I2-9 fixedly connected with a fixed rack 1-3, a driving belt IV 2-10 is matched and connected with a transmission shaft I2-4, the driving belt IV 2-10 is matched and connected with a half gear shaft I2-11, a toothed chain 2-12 is meshed and connected with the half gear shaft I2-11, a toothed chain 2-12 is meshed and connected with a half gear shaft II 2-13, a driving belt V2-14 is matched and connected with the half gear shaft I2-11, a driving belt V2-14 is matched and connected with the half gear shaft II 2-13, a half gear shaft support 2-15 is rotationally connected with the half gear shaft I2-11, a half gear shaft support 2-15 is rotationally connected with a half gear shaft II 2-13, a half gear shaft support 2-15 is fixedly connected with a fixed rack 1-3, a slide block II 2-16 is fixedly connected with the toothed chain 2-12, a slide block II 2-16 is slidably connected with a saw blade 2-22, a second fixed block 2-17 is fixedly connected with a second saw blade 2-22, a second fixed block 2-17 is slidably connected with a second bump 2-18, the second bump 2-18 is in contact with a second spring 2-19, a first sliding chute 2-20 is arranged on a first sliding block 2-8, a second groove 2-21 is arranged on the first sliding chute 2-20, the second groove 2-21 is fixedly connected with the second bump 2-18, the second saw blade 2-22 is in contact with a second bar 1-1, the second saw blade 2-22 is slidably connected with a third sliding block 2-23, the third sliding block 2-23 is slidably connected with a second sliding block support 2-25, one end of the third spring 2-24 is in contact with the third sliding block 2-23, the other end of the third spring 2-24 is in contact with a second sliding block support 2-25, and the second sliding block support 2-25 is fixedly connected with a fixed rack 1-3;

the motor 2-1 outputs the whole equipment, the transmission belt II 2-2 is matched with the motor 2-1, the transmission belt III 2-3 is matched with the motor 2-1 and the transmission shaft I2-4, the motor 2 drives the transmission belt III 2-3 to transmit, the transmission belt III 2-3 drives the transmission shaft I2-4 to rotate on the transmission shaft bracket I2-5, the transmission shaft I2-4 is connected with the rotating rod 2-6, the transmission shaft I2-4 rotates to drive the rotating rod 2-6 to rotate, the rotating rod 2-6 rotates to drive the sliding bearing 2-7 to rotate in the sliding block I2-8, so that the sliding block I2-8 slides on the sliding block bracket I2-9, the transmission belt IV 2-10 and the transmission shaft I2-4, The first half gear shaft 2-11 is matched, the first transmission shaft 2-4 drives the fourth transmission belt 2-10 to transmit, the fourth transmission belt 2-10 drives the first half gear shaft 2-11 to rotate, the first half gear shaft 2-11 and the second half gear shaft 2-13 are meshed with the gear chain 2-12, the gear chain 2-12 is connected with the second slider 2-16, the gear chain 2-12 is driven to rotate after the first half gear shaft 2-11 rotates, the gear chain 2-12 drives the second slider 2-16 to slide up and down, so that the second slider 2-16 drives the saw blade 2-22 to cut the bar 1-1, the second fixed block 2-17 is fixed with the saw blade 2-22, when the saw blade 2-22 slides, the second fixed block 2-17 fixes the saw blade 2-22 on the first slider 2-8, when the second sliding block 2-16 slides up and down, the second fixed block 2-17 drives the lug 2-18 to compress the second spring 2-19, so that the saw blade 2-22 is fixed in the groove 2-21, the first sliding block 2-8 drives the saw blade 2-22 to slide left and right to cut the bar 1-1, the second sliding block 2-16 drives the saw blade 2-22 to slide up and down, the position of the saw blade 2-22 is adjusted, the third sliding block 2-23 is sleeved at the other end of the saw blade 2-22, and the third sliding block 2-23 compresses the third spring 2-24 after the saw blade 2-22 slides, so that the saw blade 2-22 is more stable during cutting.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-10, and the embodiment further describes the first embodiment, the transmission assembly 3 includes a hinge post 3-1, a receiving plate 3-2, a spring four 3-3, a trigger block 3-4, a clutch one 3-5, a clutch two 3-6, a transmission shaft two 3-7, a transmission shaft bracket two 3-8, a transmission belt six 3-9, a worm 3-10, and a worm bracket 3-11, the hinge post 3-1 is fixedly connected with the fixed frame 1-3, the receiving plate 3-2 is rotatably connected with the hinge post 3-1, one end of the spring four 3-3 is contacted with the receiving plate 3-2, the other end of the spring four 3-3 is contacted with the fixed frame 1-3, and the trigger block 3-4 is slidably connected with the through hole 1-18, the trigger block 3-4 is fixedly connected with the clutch I3-5, the clutch I3-5 is meshed with the clutch II 3-6, the clutch II 3-6 is fixedly connected with the transmission shaft II 3-7, the transmission shaft II 3-7 is rotatably connected with the transmission shaft bracket II 3-8, the transmission shaft bracket II 3-8 is fixedly connected with the fixed rack 1-3, the transmission belt six 3-9 is in matched connection with the trigger block 3-4, the transmission belt six 3-9 is in matched connection with the worm 3-10, the worm 3-10 is rotatably connected with the worm bracket 3-11, and the worm bracket 3-11 is fixedly connected with the fixed rack 1-3.

The invention relates to automatic blanking equipment of a sawing machine, which has the working principle that: when cutting, a bar 1-1 is placed on a bar support 1-2, a fixed rack 1-3 is used for fixing the whole device, a turbine 1-4 is connected with a roller 1-5, the roller 1-5 is driven to rotate after the turbine 1-4 rotates, the roller 1-5 is matched with a conveyor belt 1-6, the conveyor belt 1-6 is driven to convey the bar 1-1, a transmission belt 1-7 is matched with the roller 1-5 and a half-cone-tooth shaft 1-8, when the conveyor belt 1-6 conveys, the roller 1-5 drives the transmission belt 1-7 to transmit, the transmission belt 1-7 drives the half-cone-tooth shaft 1-8 to rotate in a cone-tooth shaft support 1-9, the half-cone-tooth shaft 1-8 is meshed with a cone gear 1-10 after rotating, the first bevel gear 1-10 drives the cross rod 1-12 to rotate forwards, the cross rod 1-12 is connected with the lead screw 1-14, the lead screw 1-14 slides upwards to release the first spring 1-17, the first fixed block 1-16 is disconnected with the bar 1-1, so that the bar 1-1 can be conveyed on the conveyor belt 1-6, the bar 1-1 is meshed with the second bevel gear 1-11 after the half bevel gear shaft 1-8 rotates for one circle, the second bevel gear 1-11 drives the cross rod 1-12 to rotate backwards to drive the lead screw 1-1 to slide downwards, the lead screw 1-1 drives the cushion block 1-15, the first fixed block 1-16 compresses the first spring 1-17 to fix the bar 1-1, the bar is ready to be cut, and the motor 2-1 outputs the whole device, the second transmission belt 2-2 is matched with the motor 2-1, the third transmission belt 2-3 is matched with the motor 2-1 and the first transmission shaft 2-4, the motor 2 drives the third transmission belt 2-3 to transmit, the third transmission belt 2-3 drives the first transmission shaft 2-4 to rotate on the first transmission shaft bracket 2-5, the first transmission shaft 2-4 is connected with the rotating rod 2-6, the first transmission shaft 2-4 rotates to drive the rotating rod 2-6 to rotate, the rotating rod 2-6 rotates to drive the sliding bearing 2-7 to rotate in the first sliding block 2-8, so that the first sliding block 2-8 slides on the first sliding block bracket 2-9, the fourth transmission belt 2-10 is matched with the first transmission shaft 2-4 and the first half gear shaft 2-11, and the first transmission shaft 2-4 drives the fourth transmission belt 2-10 to transmit, a fourth driving belt 2-10 drives a first half gear shaft 2-11 to rotate, a first half gear shaft 2-11 and a second half gear shaft 2-13 are meshed with a toothed chain 2-12, the toothed chain 2-12 is connected with a second slider 2-16, the toothed chain 2-12 is driven to rotate after the first half gear shaft 2-11 rotates, the toothed chain 2-12 drives the second slider 2-16 to slide up and down, so that the second slider 2-16 drives a saw blade 2-22 to cut a bar 1-1, a second fixed block 2-17 is fixed with the saw blade 2-22, when the saw blade 2-22 slides, the second fixed block 2-17 fixes the saw blade 2-22 on the first slider 2-8, when the second slider 2-16 slides up and down, the second fixed block 2-17 drives a lug 2-18 to compress a second spring 2-19, the saw blade 2-22 is fixed in the groove 2-21, the first slider 2-8 drives the saw blade 2-22 to slide left and right to cut the bar 1-1, the second slider 2-16 drives the saw blade 2-22 to slide up and down to adjust the position of the saw blade 2-22, the third slider 2-23 is sleeved at the other end of the saw blade 2-22, the third slider 2-23 compresses the third spring 2-24 to make the saw blade 2-22 more stable during cutting after the saw blade 2-22 slides, the hinge post 3-1 is fixedly connected with the fixed rack 1-3, the receiving plate 3-2 receives the blank after cutting, when the receiving plate 3-2 receives, the fourth spring 3-3 of the receiving plate 3-2 compresses the fourth spring 3-3 to contact with the trigger block 3-4, the trigger block 3-4 is connected with the clutch I3-5, the trigger block 3-4 drives the clutch I3-5 to be meshed with the clutch II 3-6 after sliding, the clutch II 3-6 is connected with the transmission shaft II 3-7, the clutch II 3-6 is matched with the transmission belt II 2-2, the transmission belt II 2-2 is driven by the motor 2-1, the transmission belt II 2-2 drives the transmission shaft II 3-7 to rotate, the transmission shaft II 3-7 drives the clutch II 3-6 to rotate, after the clutch I3-5 is meshed with the clutch II 3-6, the clutch II 3-6 drives the clutch I3-5 to rotate, and the transmission belt six 3-9 is matched with the trigger block 3-4 and the worm 3-10, when the six transmission belts 3-9 are used for transmission, the worms 3-10 are driven to rotate, the worms 3-10 are meshed with the turbines 1-4, and the bars 1-1 are transmitted by the transmission belts 1-6 and then cut next time.

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 (4)

1. The utility model provides an automatic unloading equipment of sawing machine which characterized in that: the sawing machine comprises a sawing machine component (1), a cutting component (2) and a transmission component (3), wherein the sawing machine component (1) is connected with the cutting component (2), the sawing machine component (1) is connected with the transmission component (3), and the cutting component (2) is connected with the transmission component (3).

2. The automatic blanking device of the sawing machine as claimed in claim 1, wherein: the sawing machine component (1) comprises a bar (1-1), a bar support (1-2), a fixed rack (1-3), a turbine (1-4), a roller (1-5), a conveyor belt (1-6), a first conveyor belt (1-7), a semi-bevel gear shaft (1-8), a bevel gear shaft support (1-9), a first bevel gear (1-10), a second bevel gear (1-11), a cross rod (1-12), a bevel gear sleeve (1-13), a screw (1-14), a cushion block (1-15), a first fixed block (1-16), a first spring (1-17) and a through hole (1-18), wherein the bar (1-1) is in sliding connection with the bar support (1-2), and the bar (1-1) is in sliding connection with the fixed rack (1-3), the turbine (1-4) is fixedly connected with the roller (1-5), the roller (1-5) is rotatably connected with the fixed rack (1-3), the roller (1-5) is connected with the conveyor belt (1-6) in a matching way, the conveyor belt (1-6) is slidably connected with the bar (1-1), the conveyor belt I (1-7) is connected with the roller (1-5) in a matching way, the conveyor belt I (1-7) is connected with the half-cone-tooth shaft (1-8) in a matching way, the half-cone-tooth shaft (1-8) is rotatably connected with the cone-tooth shaft bracket (1-9), the cone-tooth shaft bracket (1-9) is fixedly connected with the fixed rack (1-3), the cone gear I (1-10) is connected with the half-cone-tooth shaft (1-8) in a meshing way, and the cone gear I (1-10) is slidably connected with the cross rod (1-12), a second bevel gear (1-11) is meshed with a semi-bevel gear shaft (1-8), the second bevel gear (1-11) is connected with a cross rod (1-12) in a sliding manner, a bevel gear sleeve (1-13) is rotationally connected with a first bevel gear (1-10), the bevel gear sleeve (1-13) is rotationally connected with the second bevel gear (1-11), a lead screw (1-14) is fixedly connected with the cross rod (1-12), the lead screw (1-14) is in threaded connection with a fixed rack (1-3), the lead screw (1-14) is in contact with a cushion block (1-15), the cushion block (1-15) is fixedly connected with a first fixed block (1-16), one end of the first spring (1-17) is in contact with the first fixed block (1-16), the other end of the first spring (1-17) is in contact with the fixed rack (1-3), the through holes (1-18) are arranged on the fixed frame (1-3).

3. The automatic blanking device of the sawing machine as claimed in claim 1, wherein: the cutting component (2) comprises a motor (2-1), a transmission belt II (2-2), a transmission belt III (2-3), a transmission shaft I (2-4), a transmission shaft support I (2-5), a rotating rod (2-6), a sliding bearing (2-7), a sliding block I (2-8), a sliding block support I (2-9), a transmission belt IV (2-10), a half gear shaft I (2-11), a toothed chain (2-12), a half gear shaft II (2-13), a transmission belt V (2-14), a half gear shaft support (2-15), a sliding block II (2-16), a fixed block II (2-17), a convex block (2-18), a spring II (2-19), a sliding groove (2-20), a groove (2-21), a saw blade (2-22), A third sliding block (2-23), a third spring (2-24) and a second sliding block support (2-25), wherein the motor (2-1) is fixedly connected with the fixed rack (1-3), the motor (2-1) is connected with the second transmission belt (2-2) in a matching way, the motor (2-1) is connected with the third transmission belt (2-3) in a matching way, the third transmission belt (2-3) is connected with the first transmission shaft (2-4) in a matching way, the first transmission shaft (2-4) is rotationally connected with the first transmission shaft support (2-5), the first transmission shaft support (2-5) is fixedly connected with the fixed rack (1-3), the rotating rod (2-6) is fixedly connected with the first transmission shaft (2-4), the rotating rod (2-6) is slidably connected with the sliding bearing (2-7), and the sliding bearing (2-7) is rotationally connected with the first sliding block (2-8), a first sliding block (2-8) is connected with a first sliding block support (2-9) in a sliding manner, the first sliding block support (2-9) is fixedly connected with a fixed rack (1-3), a fourth transmission belt (2-10) is connected with a first transmission shaft (2-4) in a matching manner, the fourth transmission belt (2-10) is connected with a first half gear shaft (2-11) in a matching manner, a toothed chain (2-12) is connected with the first half gear shaft (2-11) in a meshing manner, a toothed chain (2-12) is connected with a second half gear shaft (2-13) in a meshing manner, a fifth transmission belt (2-14) is connected with the first half gear shaft (2-11) in a matching manner, a fifth transmission belt (2-14) is connected with the second half gear shaft (2-13) in a matching manner, and a bracket (2-15) of the second half gear shaft is connected with the first half gear shaft (2-11) in a rotating manner, the half gear shaft support (2-15) is rotationally connected with the half gear shaft II (2-13), the half gear shaft support (2-15) is fixedly connected with the fixed rack (1-3), the slide block II (2-16) is fixedly connected with the toothed chain (2-12), the slide block II (2-16) is slidably connected with the saw blade (2-22), the fixed block II (2-17) is fixedly connected with the saw blade (2-22), the fixed block II (2-17) is slidably connected with the bump (2-18), the bump (2-18) is contacted with the spring II (2-19), the chute (2-20) is arranged on the slide block I (2-8), the groove (2-21) is arranged on the chute (2-20), and the groove (2-21) is fixedly connected with the bump (2-18), the saw blade (2-22) is in contact with the bar (1-1), the saw blade (2-22) is in sliding connection with the third sliding block (2-23), the third sliding block (2-23) is in sliding connection with the second sliding block support (2-25), one end of the third spring (2-24) is in contact with the third sliding block (2-23), the other end of the third spring (2-24) is in contact with the second sliding block support (2-25), and the second sliding block support (2-25) is fixedly connected with the fixed rack (1-3).

4. The automatic blanking device of the sawing machine as claimed in claim 1, wherein: the transmission assembly (3) comprises a hinged column (3-1), a receiving plate (3-2), a spring IV (3-3), a trigger block (3-4), a clutch I (3-5), a clutch II (3-6), a transmission shaft II (3-7), a transmission shaft bracket II (3-8), a transmission belt VI (3-9), a worm (3-10) and a worm bracket (3-11), the hinged column (3-1) is fixedly connected with the fixed rack (1-3), the receiving plate (3-2) is rotatably connected with the hinged column (3-1), one end of the spring IV (3-3) is contacted with the receiving plate (3-2), the other end of the spring IV (3-3) is contacted with the fixed rack (1-3), the trigger block (3-4) is in sliding connection with the through hole (1-18), the trigger block (3-4) is fixedly connected with the clutch I (3-5), the clutch I (3-5) is meshed with the clutch II (3-6), the clutch II (3-6) is fixedly connected with the transmission shaft II (3-7), the transmission shaft II (3-7) is rotatably connected with the transmission shaft bracket II (3-8), the transmission shaft bracket II (3-8) is fixedly connected with the fixed rack (1-3), the transmission belt VI (3-9) is matched and connected with the trigger block (3-4), the transmission belt VI (3-9) is matched and connected with the worm (3-10), the worm (3-10) is rotatably connected with the worm bracket (3-11), and the worm bracket (3-11) is fixedly connected with the fixed rack (1-3).

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