CN210389353U - Automatic nylon tube blanking machine - Google Patents

Abstract

The utility model discloses an automatic nylon tube blanking machine, belonging to the technical field of nylon tube processing equipment, comprising a frame, wherein one end of the frame is fixedly connected with a feeding frame, the feeding frame is rotationally connected with an upper rotating wheel and a lower rotating wheel, the circumferential surfaces of the upper rotating wheel and the lower rotating wheel are both provided with arc grooves, and the arc grooves of the upper rotating wheel and the arc grooves of the lower rotating wheel form channels; frame other end fixedly connected with box, feed inlet and discharge gate have been seted up to the box, box fixedly connected with servo motor, servo motor's output shaft fixedly connected with axis of rotation, axis of rotation fixedly connected with cutter, pivot under the lower runner fixedly connected with, servo motor are connected with control circuit, and control circuit can the automatic calculation down the rotation number of turns of pivot and control servo motor start, the utility model discloses have the length that can the automatic calculation nylon tube and cut, guarantee that every section nylon tube cuts the accurate effect of length.

Description

Automatic nylon tube blanking machine

Technical Field

The utility model belongs to the technical field of the technique of nylon tube processing equipment and specifically relates to a nylon tube automatic blanking machine is related to.

Background

At present, pipelines such as nylon pipes are cut by a cutter, and a factory can cut the nylon pipes by a nylon pipe blanking machine when the required number of the nylon pipes is large.

Prior art can refer to the chinese utility model patent that the publication number of authorizing is CN208392109U, it discloses a nylon tube blanking machine, include: the reel is wound with at least one pipeline and used for discharging the pipeline; the fixing frame is arranged along the feeding direction of the pipeline; the long edge of the fixing frame is parallel to the feeding direction of the pipeline; the pipeline positioning and guiding device is arranged at one end of the fixed frame close to the reel and used for guiding the pipeline to move along a straight line; the pipeline moving device is arranged on the fixed frame and used for driving the pipeline to move along a straight line; the pipeline cutting device is arranged on the fixed frame and arranged between the pipeline positioning and guiding device and the pipeline moving device, and the pipeline cutting device is used for cutting off the pipeline.

The above prior art solutions have the following drawbacks: above-mentioned blanking machine is difficult to accurately carry out the fixed length to the nylon tube when cutting the nylon tube and cuts.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a nylon tube automatic blanking machine can the length of automatic calculation nylon tube and cut, guarantees that every section nylon tube cuts length accuracy.

The above technical purpose of the present invention can be achieved by the following technical solutions:

an automatic nylon tube blanking machine comprises a machine frame, wherein one end of the machine frame is fixedly connected with a feeding frame, the feeding frame is rotatably connected with an upper rotating wheel and a lower rotating wheel, the circumferential surfaces of the upper rotating wheel and the lower rotating wheel are respectively provided with an arc-shaped groove, the upper rotating wheel and the lower rotating wheel are mutually abutted, and the arc-shaped grooves of the upper rotating wheel and the lower rotating wheel form a channel with the same cross section area as that of a nylon tube;

the other end of the rack is fixedly connected with a box body, one surface of the box body, which is close to the feeding frame, is provided with a feeding hole, the feeding hole and the channel are positioned at the same horizontal height, the other surface of the box body is provided with a discharging hole, and the nylon pipe can move from the feeding hole to the discharging hole;

a servo motor is fixedly connected to the position, close to the feed port, of the box body, an output shaft of the servo motor is fixedly connected with a rotating shaft, the rotating shaft is rotatably connected into the box body, a cutter is fixedly connected to the position, corresponding to the position inside the box body, of the rotating shaft, and the rotating shaft can drive the cutter to rotate to the position of the feed port;

the lower rotating wheel is fixedly connected with a lower rotating shaft, the lower rotating shaft and the lower rotating wheel are coaxial, the servo motor is connected with a control circuit, and the control circuit further comprises a circle number acquisition module, a circle number comparison module and a motor control module;

the circle number acquisition module comprises a meter counter fixedly connected to the lower rotating shaft, and the meter counter acquires the number of turns of the lower rotating shaft in real time and outputs a digital signal;

the turn number comparison module is connected with the turn number acquisition module and receives the digital signal output by the turn number acquisition module, the turn number comparison module compares the received digital signal with a preset value, and when the digital signal is equal to the preset value, the turn number comparison module outputs a control signal and controls the meter counter to reset and count;

the motor control module is connected with the turn number comparison module and responds to the control signal output by the turn number comparison module, and the motor control module controls the servo motor to rotate the cutter to perform one-time cutting after receiving the control signal.

By adopting the scheme, the nylon pipe enters the blanking machine from the channel between the upper rotating wheel and the lower rotating wheel, moves to the feeding port, enters the box body from the feeding port and leaves the box body from the discharging port; the nylon pipe is when passing through the passageway, because nylon pipe and last runner and lower runner butt, so can drive runner and lower runner and rotate, the meter rice ware can note the rotation number of turns of pivot, because the longitudinal section girth of lower runner is certain, so control circuit only need start servo motor when the rotation number of turns of meter rice ware record reaches the default, servo motor drives the cutter and rotates, cuts off the nylon pipe in the box, can guarantee that every section nylon pipe cuts length accuracy.

The utility model discloses further set up to: an upper fixing block is fixedly connected to the position, close to the upper rotating wheel, of the feeding frame, an upper connecting block is rotatably connected to the upper fixing block, an upper rotating shaft is rotatably connected to the position, close to the upper rotating wheel, of the upper connecting block, the upper rotating shaft is fixedly connected to the upper rotating wheel, and the upper rotating shaft and the upper rotating wheel are coaxial;

the feeding frame is fixedly connected with a lower fixing block at a position close to the lower rotating wheel, the lower fixing block is rotatably connected with a lower connecting block, and the lower rotating shaft is rotatably connected to the lower connecting block.

Through adopting above-mentioned scheme, the user can adjust the level of passageway through rotating connecting block and lower connecting block to the level when adaptation nylon tube gets into.

The utility model discloses further set up to: go up articulated on the connecting block and have the synchronizing bar, the synchronizing bar is kept away from connecting rod one end and is articulated on connecting block down.

Through adopting above-mentioned scheme, the synchronizing bar can guarantee that runner and runner relative position do not change down, guarantees that the arc wall can form the passageway.

The utility model discloses further set up to: the frame corresponds fixedly connected with landing leg of position department between feeding frame and the box, and frame one end fixedly connected with arc is kept away from to the landing leg, and the arc sets up along the direction of transportation of nylon tube, and the arc is located same horizontal plane with the passageway.

Through adopting above-mentioned scheme, the nylon pipe that the blanking machine was got into by the passageway to the arc bearing guarantees that the nylon pipe can get into inside the box smoothly by the feed inlet.

The utility model discloses further set up to: the bottom of the arc plate is provided with a through groove arranged along the length of the arc plate.

Through adopting above-mentioned scheme, lead to the area of contact that can reduce arc and nylon tube in the groove, reduce the frictional force of arc to nylon tube.

The utility model discloses further set up to: the cross section area of the feed inlet is smaller than that of the discharge outlet.

Through adopting above-mentioned scheme, because nylon tube can lose the connection with nylon tube at the back after cutting in the box, the nylon tube that is close to discharge gate department can incline a little downwards, and great discharge gate can guarantee that nylon tube can leave the blanking machine smoothly from the discharge gate.

The utility model discloses further set up to: the inside cutter both sides position punishment that corresponds of box do not rotates and is connected with first conveying roller and second conveying roller, and first conveying roller is located the second conveying roller and is close to feed inlet one side, and feed inlet, first conveying roller, second conveying roller and discharge gate are located same longitudinal section, and first conveying roller and second conveying roller are connected with the first conveying roller of drive and second conveying roller syntropy pivoted drive assembly jointly.

Through adopting above-mentioned scheme, the nylon pipe gets into the box inside back from the feed inlet, at first fall on first conveying roller, first conveying roller can drive the nylon pipe and continue to advance under drive assembly's drive, move to on the second conveying roller, be cut off the back at the nylon pipe by the cutter, the nylon pipe that cuts off can continue to advance under the drive of second conveying roller, even there is flagging trend after the nylon pipe on the first conveying roller cuts off, can be lifted up by the second conveying roller after contacting the second conveying roller, guarantee that the nylon pipe can be smoothly from the discharge gate and leave the blanking machine.

The utility model discloses further set up to: a plurality of shifting blocks are fixedly connected to the circumferential surface of the second conveying roller.

Through adopting above-mentioned scheme, the shifting block can make the second conveying roller drive the nylon tube more easily and remove.

The utility model discloses further set up to: the driving assembly comprises a first transmission shaft fixedly connected in the middle of the first conveying roller and a second transmission shaft fixedly connected in the middle of the second conveying roller, the first conveying roller and the first transmission shaft are coaxial, the second conveying roller and the second transmission shaft are coaxial, the first transmission shaft fixedly connected with belt wheel, the second transmission shaft fixedly connected with second belt wheel, the first belt wheel and the second belt wheel are sleeved with a belt together, the box body corresponds to a belt position fixedly connected with driving motor, the output shaft fixedly connected with driving belt wheel of the driving motor, and the driving belt wheel is sleeved in the belt.

By adopting the above scheme, driving motor drives driving pulley and rotates, and driving pulley passes through the belt and drives first band pulley and second band pulley syntropy and rotate, and first band pulley and second band pulley drive first conveying roller and second conveying roller respectively and rotate.

To sum up, the utility model discloses following beneficial effect has:

1. the nylon pipe enters the blanking machine through a channel between the upper rotating wheel and the lower rotating wheel, moves to the feeding port, enters the box body through the feeding port and leaves the box body from the discharging port; when the nylon tube passes through the channel, the nylon tube is abutted against the upper rotating wheel and the lower rotating wheel, so that the upper rotating wheel and the lower rotating wheel can be driven to rotate, the meter counter can record the number of rotating turns of the rotating shaft, and the circumference of the longitudinal section of the lower rotating wheel is fixed, so that the control circuit only needs to start the servo motor when the number of rotating turns recorded by the meter counter reaches a preset value, the servo motor drives the cutter to rotate, the nylon tube in the box body is cut off, and the accurate cutting length of each section of nylon tube can be ensured;

2. the nylon pipe in the box body loses the connection with the nylon pipe behind after being cut, the nylon pipe close to the discharge port may incline downwards slightly, and the larger discharge port can ensure that the nylon pipe can smoothly leave the blanking machine from the discharge port;

3. inside back of feed inlet entering box is followed to the nylon pipe, at first fall on first conveying roller, first conveying roller can drive the nylon pipe under drive assembly's drive and continue to advance, remove to the second conveying roller on, the nylon pipe is cut off the back by the cutter, the nylon pipe that cuts off can continue to advance under the drive of second conveying roller, even there is flagging trend after cutting off the nylon pipe on the first conveying roller, can be lifted up by the second conveying roller after contacting the second conveying roller, guarantee that the nylon pipe can be smoothly from the discharge gate and leave the blanking machine.

Drawings

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

FIG. 2 is an exploded view of the protruded feed frame of the example;

FIG. 3 is a schematic view of a protruding channel in an embodiment;

FIG. 4 is a schematic view of a protruding arc plate in the embodiment;

FIG. 5 is a sectional view showing the inner structure of the protruding case in the embodiment;

FIG. 6 is a schematic view of a protruding cutter and drive assembly in an embodiment;

FIG. 7 is a schematic circuit diagram of a projected turn number collecting module and a turn number comparing module in the embodiment;

FIG. 8 is a schematic circuit diagram of a salient motor control module in an embodiment.

In the figure, 1, a frame; 11. an arc-shaped plate; 111. a support leg; 112. a through groove; 2. a feeding frame; 21. an upper runner; 211. an arc-shaped slot; 2111. a channel; 212. an upper fixed block; 213. an upper connecting block; 214. an upper rotating shaft; 215. a synchronization lever; 22. a lower runner; 221. a lower fixed block; 222. a lower connecting block; 223. a lower rotating shaft; 3. a box body; 31. a feed inlet; 32. a discharge port; 33. a servo motor; 331. a rotating shaft; 332. a cutter; 34. a first conveying roller; 35. a second conveying roller; 351. shifting blocks; 36. a drive assembly; 361. a first drive shaft; 362. a second drive shaft; 363. a first pulley; 364. a second pulley; 365. a belt; 366. a driving pulley; 367. a drive motor; 4. a circle number acquisition module; 41. a meter counter; 5. a circle number comparison module; 6. and a motor control module.

Detailed Description

Example (b): an automatic nylon tube blanking machine is shown in figures 1 and 2 and comprises a machine frame 1, wherein one end of the machine frame 1 is fixedly connected with a feeding frame 2, the other end of the machine frame 1 is fixedly connected with a box body 3, and an upper rotating wheel 21 and a lower rotating wheel 22 are arranged on the feeding frame 2. The nylon tube enters a blanking machine from the space between the upper rotating wheel 21 and the lower rotating wheel 22 and then moves to the box body 3 for cutting.

As shown in fig. 2 and 3, the circumferential surfaces of the upper runner 21 and the lower runner 22 are both provided with an arc-shaped groove 211, the upper runner 21 and the lower runner 22 are abutted against each other, and the arc-shaped groove 211 of the upper runner 21 and the arc-shaped groove 211 of the lower runner 22 form a channel 2111 with the same cross-sectional area as the nylon tube. When the nylon tube passes through the channel 2111, the nylon tube is abutted to the upper rotating wheel 21 and the lower rotating wheel 22, and the upper rotating wheel 21 and the lower rotating wheel 22 can be driven to rotate.

As shown in fig. 2, an upper fixing block 212 is fixedly connected to a position of the feeding frame 2 close to the upper rotating wheel 21, the upper fixing block 212 is rotatably connected to an upper connecting block 213, the position of the upper connecting block 213 close to the upper rotating wheel 21 is rotatably connected to an upper rotating shaft 214, the upper rotating shaft 214 is fixedly connected to the upper rotating wheel 21, and the upper rotating shaft 214 and the upper rotating wheel 21 are coaxial. The position of the feeding frame 2 close to the lower rotating wheel 22 is fixedly connected with a lower fixing block 221, the lower fixing block 221 is rotatably connected with a lower connecting block 222, the position of the lower connecting block 222 close to the lower rotating wheel 22 is rotatably connected with a lower rotating shaft 223, the lower rotating shaft 223 is fixedly connected with the lower rotating wheel 22, and the lower rotating shaft 223 and the lower rotating wheel 22 are coaxial. The user can adjust the level of the channel 2111 by rotating the upper connecting block 213 and the lower connecting block 222 to adapt to the level of the nylon tube when entering.

As shown in fig. 2, the upper connecting block 213 is hinged with a synchronizing rod 215, and one end of the synchronizing rod 215 far away from the upper connecting rod is hinged on the lower connecting block 222. The synchronization rod 215 ensures that the relative positions of the upper runner 21 and the lower runner 22 are unchanged, and that the arc-shaped slot 211 can form the channel 2111.

As shown in fig. 1 and 4, a supporting leg 111 is fixedly connected to the frame 1 at a position corresponding to a position between the feeding frame 2 and the box 3, and an arc plate 11 is fixedly connected to one end of the supporting leg 111 far away from the frame 1. The arc plate 11 is arranged along the transportation direction of the nylon pipe, and the arc plate 11 and the channel 2111 are positioned on the same horizontal plane. The bottom of the arc plate 11 is provided with a through groove 112 arranged along the length of the arc plate 11. The arc plate 11 supports the nylon pipe entering the blanking machine through the channel 2111, and the nylon pipe can smoothly enter the box body 3 through the feeding hole 31. The through groove 112 can reduce the contact area between the arc plate 11 and the nylon tube, so as to reduce the friction force of the arc plate 11 to the nylon tube.

As shown in fig. 4, a feeding port 31 is formed on one surface of the box body 3 close to the feeding frame 2, the feeding port 31 and the channel 2111 are located at the same horizontal height, a discharging port 32 is formed on the other surface of the box body 3, and the nylon tube can move from the feeding port 31 to the discharging port 32. The cross-sectional area of the inlet port 31 is smaller than the cross-sectional area of the outlet port 32.

As shown in fig. 4 and 5, a servo motor 33 is fixedly connected to the box 3 near the feed opening 31, a rotating shaft 331 is fixedly connected to an output shaft of the servo motor 33, and the rotating shaft 331 is rotatably connected to the inside of the box 3. The rotating shaft 331 is fixedly connected with the cutter 332 corresponding to the inner position of the box body 3, and the rotating shaft 331 can drive the cutter 332 to rotate to the position of the feed port 31. The servo motor 33 drives the cutter 332 to rotate, so that the nylon tube in the box body 3 can be cut off.

As shown in fig. 4 and 5, the first conveying roller 34 and the second conveying roller 35 are rotatably connected to the inside of the box 3 corresponding to the two sides of the cutting knife 332, the first conveying roller 34 is located on one side of the second conveying roller 35 close to the feeding opening 31, and the circumferential surface of the second conveying roller 35 is fixedly connected with a plurality of shifting blocks 351. The feed opening 31, the first conveyor roller 34, the second conveyor roller 35 and the discharge opening 32 are located on the same longitudinal section. Inside back of feed inlet 31 entering box 3 is followed to the nylon tube, at first fall to first conveying roller 34, first conveying roller 34 can drive the nylon tube under drive assembly 36's drive and continue to advance, move to on second conveying roller 35, after the nylon tube is cut off by cutter 332, the nylon tube that cuts off can continue to advance under the drive of second conveying roller 35, even there is flagging trend after the nylon tube on first conveying roller 34 cuts off, can be lifted by second conveying roller 35 after contacting second conveying roller 35, guarantee that the nylon tube can be smoothly from discharge gate 32 departure blanking machine.

As shown in fig. 4 and 5, the first conveying roller 34 and the second conveying roller 35 are commonly connected to a driving assembly 36, and the driving assembly 36 includes a first transmission shaft 361 fixedly connected to the middle of the first conveying roller 34 and a second transmission shaft 362 fixedly connected to the middle of the second conveying roller 35. The first conveying roller 34 is coaxial with the first transmission shaft 361, and the second conveying roller 35 is coaxial with the second transmission shaft 362. The first transmission shaft 361 is fixedly connected with a first belt wheel 363, the second transmission shaft 362 is fixedly connected with a second belt wheel 364, and a belt 365 is sleeved outside the first belt wheel 363 and the second belt wheel 364 together. The box body 3 is fixedly connected with a driving motor 367 at a position corresponding to the belt 365, an output shaft of the driving motor 367 is fixedly connected with a driving belt wheel 366, and the driving belt wheel 366 is sleeved in the belt 365. The driving motor 367 drives the driving pulley 366 to rotate, the driving pulley 366 drives the first pulley 363 and the second pulley 364 to rotate in the same direction through the belt 365, and the first pulley 363 and the second pulley 364 drive the first conveying roller 34 and the second conveying roller 35 to rotate respectively.

As shown in fig. 7 and 8, the servo motor 33 is connected to a control circuit, and the control circuit further includes a turn number collecting module 4, a turn number comparing module 5 and a motor control module 6. The lap number collecting module 4 comprises a meter counter 41 (see fig. 2) fixedly connected to the lower rotating shaft 223, and the meter counter 41 collects the lap number of the rotation of the lower rotating shaft 223 in real time and outputs a digital signal.

As shown in fig. 7, the turn number comparing module 5 includes a comparator T electrically connected to one end of the meter counter 41, an output end of the meter counter 41 is electrically connected to a positive input end of the comparator T, and the preset value Vref is input to the comparator T from a negative input end of the comparator T. The output of the comparator T is electrically connected to the meter counter 41. The output end of the comparator T is electrically connected with a triode Q, the base electrode of the triode Q is electrically connected with the output end of the comparator T, the collector electrode of the triode Q is electrically connected with a resistor R, the other end of the resistor R is electrically connected with a power supply VCC, the emitter electrode of the triode Q is electrically connected with an electromagnetic coil KA1, and the other end of the electromagnetic coil KA1 is grounded.

As shown in FIG. 8, the motor control module 6 comprises a solenoid KA2 of the relay, a normally open contact KA1-1 of the relay, a solenoid KT1 of the electrified time delay relay and a normally closed contact KT1-1 of the electrified time delay relay which are connected with the servo motor 33 in series. The normally open contact KA2-1 of the relay is connected in parallel with the two ends of the normally open contact KA1-1 of the relay. One end of an electromagnetic coil KA2 of the relay is electrically connected with a power supply VCC. One end of a normally closed contact KT1-1 of the electrified time delay relay is grounded.

The use method comprises the following steps: the nylon tube enters the blanking machine through a channel 2111 between the upper rotating wheel 21 and the lower rotating wheel 22, the nylon tube drives the upper rotating wheel 21 and the lower rotating wheel 22 to rotate when passing through the channel 2111, the meter counter 41 collects the number of rotating turns of the lower rotating shaft 223 in real time and outputs a digital signal, the comparator T receives the digital signal and compares the received digital signal with a preset value Vref, and when the digital signal is equal to the preset value Vref, the comparator T outputs a high-level signal. The meter counter 41 clears the count after receiving the high level signal. The collector and the emitter of the triode Q are conducted, the electromagnetic coil KA1 of the relay is electrified, the normally open contact KA1-1 of the relay is controlled to be closed, the electromagnetic coil KA2 of the relay is electrified, and the normally open contact KA2-1 of the relay is controlled to be closed. The driving motor 367 and an electromagnetic coil KT1 of the electrified delay time relay are electrified, and the driving motor 367 controls the cutter 332 to rotate to cut the nylon tube. After the electromagnetic coil KT1 of the electrified time delay relay rotates for a circle, the normally closed contact KT1-1 of the electrified time delay relay is controlled to be disconnected, and the electromagnetic coil KA2 of the relay and the driving motor 367 lose power.

The control circuit only needs to start the servo motor 33 when the number of rotation turns recorded by the meter counter 41 reaches a preset value, the servo motor 33 drives the cutter 332 to rotate, the nylon tube in the box body 3 is cut off, and the accurate cutting length of each section of nylon tube can be ensured.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (9)

1. The utility model provides a nylon tube automatic blanking machine, includes frame (1), its characterized in that: one end of the rack (1) is fixedly connected with a feeding frame (2), an upper rotating wheel (21) and a lower rotating wheel (22) are rotatably connected onto the feeding frame (2), arc-shaped grooves (211) are formed in the circumferential surfaces of the upper rotating wheel (21) and the lower rotating wheel (22), the upper rotating wheel (21) and the lower rotating wheel (22) are mutually abutted, and a channel (2111) with the same area as the cross section of the nylon pipe is formed in each arc-shaped groove (211) of the upper rotating wheel (21) and each arc-shaped groove (211) of the lower rotating wheel (22);

the other end of the rack (1) is fixedly connected with a box body (3), one side, close to the feeding frame (2), of the box body (3) is provided with a feeding hole (31), the feeding hole (31) and the channel (2111) are located at the same horizontal height, the other side of the box body (3) is provided with a discharging hole (32), and the nylon tube can move from the feeding hole (31) to the discharging hole (32);

a servo motor (33) is fixedly connected to the position, close to the feed port (31), of the box body (3), an output shaft of the servo motor (33) is fixedly connected with a rotating shaft (331), the rotating shaft (331) is rotatably connected into the box body (3), a cutter (332) is fixedly connected to the position, corresponding to the inner part of the box body (3), of the rotating shaft (331), and the rotating shaft (331) can drive the cutter (332) to rotate to the position of the feed port (31);

the lower rotating wheel (22) is fixedly connected with a lower rotating shaft (223), the lower rotating shaft (223) and the lower rotating wheel (22) are coaxial, the servo motor (33) is connected with a control circuit, and the control circuit further comprises a circle number acquisition module (4), a circle number comparison module (5) and a motor control module (6);

the circle number acquisition module (4) comprises a meter counter (41) fixedly connected to the lower rotating shaft (223), and the meter counter (41) acquires the number of circles of rotation of the lower rotating shaft (223) in real time and outputs a digital signal;

the turn number comparison module (5) is connected with the turn number acquisition module (4) and receives the digital signal output by the turn number acquisition module (4), the turn number comparison module (5) compares the received digital signal with a preset value, and when the digital signal is equal to the preset value, the turn number comparison module (5) outputs a control signal and controls the meter counter (41) to be reset and counted;

the motor control module (6) is connected with the turn number comparison module (5) and responds to the control signal output by the turn number comparison module (5), and the motor control module (6) controls the servo motor (33) to rotate the angle of the cutter (332) for cutting once after receiving the control signal.

2. The automatic nylon tube blanking machine of claim 1, wherein: an upper fixing block (212) is fixedly connected to the position, close to the upper rotating wheel (21), of the feeding frame (2), the upper fixing block (212) is rotatably connected with an upper connecting block (213), the position, close to the upper rotating wheel (21), of the upper connecting block (213) is rotatably connected with an upper rotating shaft (214), the upper rotating shaft (214) is fixedly connected to the upper rotating wheel (21), and the upper rotating shaft (214) and the upper rotating wheel (21) are coaxial;

the position of the feeding frame (2) close to the lower rotating wheel (22) is fixedly connected with a lower fixing block (221), the lower fixing block (221) is rotatably connected with a lower connecting block (222), and a lower rotating shaft (223) is rotatably connected onto the lower connecting block (222).

3. The automatic nylon tube blanking machine of claim 2, wherein: the upper connecting block (213) is hinged with a synchronous rod (215), and one end, far away from the upper connecting rod, of the synchronous rod (215) is hinged on the lower connecting block (222).

4. The automatic nylon tube blanking machine of claim 1, wherein: frame (1) corresponds fixedly connected with landing leg (111) of position department between feed frame (2) and box (3), and frame (1) one end fixedly connected with arc (11) are kept away from to landing leg (111), and the direction of transportation setting of nylon pipe is followed in arc (11), and arc (11) are located same horizontal plane with passageway (2111).

5. The automatic nylon tube blanking machine of claim 4, wherein: the bottom of the arc-shaped plate (11) is provided with a through groove (112) which is arranged along the length of the arc-shaped plate (11).

6. The automatic nylon tube blanking machine of claim 1, wherein: the cross-sectional area of the feed opening (31) is smaller than that of the discharge opening (32).

7. The automatic nylon tube blanking machine of claim 1, wherein: the inside cutter (332) both sides position that corresponds of box (3) is rotated respectively and is connected with first conveying roller (34) and second conveying roller (35), first conveying roller (34) are located second conveying roller (35) and are close to feed inlet (31) one side, feed inlet (31), first conveying roller (34), second conveying roller (35) and discharge gate (32) are located same longitudinal section, first conveying roller (34) and second conveying roller (35) are connected with first conveying roller of drive (34) and second conveying roller (35) syntropy pivoted drive assembly (36) jointly.

8. The automatic nylon tube blanking machine of claim 7, wherein: a plurality of shifting blocks (351) are fixedly connected to the circumferential surface of the second conveying roller (35).

9. The automatic nylon tube blanking machine of claim 7, wherein: drive assembly (36) include first transmission shaft (361) and second transmission shaft (362) of fixed connection in the middle of first conveying roller (34) in the middle of second conveying roller (35), first conveying roller (34) and first transmission shaft (361) are coaxial, second conveying roller (35) and second transmission shaft (362) are coaxial, first transmission shaft (361) fixedly connected with first band pulley (363), second transmission shaft (362) fixedly connected with second band pulley (364), first band pulley (363) and second band pulley (364) overlap jointly and are equipped with belt (365), box (3) correspond belt (365) position department fixedly connected with driving motor (367), the output shaft fixedly connected with driving pulley (366) of driving motor (367), driving pulley (366) cover is located in belt (365).

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