CN113523413B - Anchor rod oblique head shearing device - Google Patents

Abstract

The invention discloses an anchor rod oblique head shearing device which comprises a base; the first supporting plates and the belt wheel are arranged between the first supporting plates; the transmission belt is sleeved on the belt wheel and is provided with a stop block; the rotating shaft is connected with the belt wheel, and one end of the rotating shaft is connected with a first motor; the telescopic rod is arranged on the base, the upper end of the telescopic rod is provided with a bracket, and the bracket is provided with a pneumatic rod; the side surface of the bracket is provided with a guide rail which is matched with the base; the second supporting plate is arranged on the bracket; the roll shaft is arranged between the second supporting plates, and one end of the roll shaft is connected with a chain wheel and is connected with a second motor; the roller is sleeved on the roller shaft and positioned between the second supporting plates, and the roller forms a conveying line; the chain is annularly arranged on the chain wheel; the guide plate is arranged on the bracket, and a first guide plate, a second guide plate, a third guide plate, a fourth guide plate and a fifth guide plate are sequentially arranged from one side close to the base to one side far away from the base; and the shearing machine is arranged at the end part of the bracket. The synchronous shearing device has the advantages of reliable feeding, synchronous conveying of multiple materials and synchronous shearing.

Description

Anchor rod oblique head shearing device

Technical Field

The invention relates to the technical field of mechanical manufacturing and anchor rod shearing equipment, in particular to an anchor rod oblique head shearing device.

Background

At present, when the oblique head is sheared by the anchor rod, one person holds the anchor rod by a shearing machine, the production efficiency is low, the existing shearing and feeding are easy, a conveying line can feed a plurality of anchor rods, and the feeding reliability is poor.

Disclosure of Invention

The invention mainly aims to provide an anchor rod oblique head shearing device to solve the problems that in the prior art, when an anchor rod shears an oblique head, one anchor rod is held by one person and a shearing machine shears one anchor rod, the production efficiency is low, the existing shearing and feeding are easy to feed a plurality of anchor rods by one conveying line, and the feeding reliability is poor.

In order to achieve the above object, the present invention provides a shear device for a slant head of a rock bolt, comprising: a base;

the first supporting plates are symmetrically arranged on the base in a matrix manner;

the belt wheels are arranged between the first supporting plates and are positioned at two ends of the first supporting plates;

the transmission belt is sleeved on the belt wheel and is provided with stop blocks arranged in a matrix manner;

the rotating shaft is connected with the belt wheel, and one end of the rotating shaft is connected with a first motor;

the telescopic rods are arranged on the base in a matrix manner, the upper ends of the telescopic rods are provided with brackets, and pneumatic rods are arranged on the brackets;

the side surface of the bracket is provided with a guide rail which is matched with the base;

the second supporting plates are arranged on the bracket in parallel in a matrix manner;

the roll shafts are arranged between the second supporting plates in a matrix manner, one ends of the roll shafts are connected with chain wheels, and the end part chain wheels are connected with a second motor; and

the roller is sleeved on the roller shaft and positioned between the second supporting plates, and the roller forms a conveying line;

the chain is annularly arranged on the chain wheel and matched with the chain wheel;

the guide plate is arranged on the bracket, and a first guide plate, a second guide plate, a third guide plate, a fourth guide plate and a fifth guide plate are sequentially arranged from one side close to the base to one side far away from the base;

and the shearing machine is arranged at the end part of the bracket.

Preferably, the first motor drives the rotating shaft to rotate, the rotating shaft drives the belt wheel to rotate, the belt wheel drives the transmission belt to rotate, the transmission belt drives the stop block to move, and the transmission belt and the stop block drive the anchor rod material to move horizontally towards the conveying line.

Preferably, the second motor drives one of the chain wheels to rotate, so as to drive the chain to transmit, the chain drives other chain wheels to rotate, the chain wheel drives the roll shaft to rotate, the roll shaft drives the roll wheel to rotate, and the roll wheel drives the anchor rod material to be conveyed towards the shearing machine.

Preferably, the stock material is laid on the drive belt through the dog interval, the transfer chain parallel sets up side by side, stock material both ends and middle lower extreme receive the drive belt respectively and support, and drive belt quantity includes three at least, the pivot links to each other with the band pulley of every drive belt, link to each other through rolling bearing between pivot and the first backup pad.

Preferably, the first guide plate, the second guide plate, the third guide plate, the fourth guide plate and the fifth guide plate each include a vertical portion and an inclined portion, wherein the heights of the vertical parts of the first guide plate, the second guide plate, the third guide plate, the fourth guide plate and the fifth guide plate are sequentially increased, the lengths of the inclined parts are sequentially increased, a first guide channel is formed between the first guide plate and the second guide plate, a second guide channel is formed between the second guide plate and the third guide plate, a third flow guide channel is formed between the third guide plate and the fourth guide plate, a fourth flow guide channel is formed between the fourth guide plate and the fifth guide plate, the opening of the first diversion channel is positioned right above the first anchor rod material close to the guide rail, the opening of the second diversion channel is positioned right above the second anchor rod material close to the guide rail, the opening of the third flow guide channel is positioned right above a third anchor rod material close to the guide rail, and the opening of the fourth flow guide channel is positioned right above a fourth anchor rod material close to the guide rail.

Preferably, the telescopic link includes first telescopic link, second telescopic link, third telescopic link, fourth telescopic link, first telescopic link is located and is close to under the first stock material of guide rail, the second telescopic link is located and is close to under the second stock material of guide rail, the third telescopic link is located and is close to under the third stock material of guide rail, the fourth telescopic link is located and is close to under the fourth stock material of guide rail, every telescopic link upper end all is equipped with L type bracket, the bracket diaphragm is close to the edge and is equipped with the pneumatic link.

Preferably, the telescopic link drives the bracket and rises and descends, the bracket holds up stock material to the crossing department of water conservancy diversion way, and wherein the diaphragm of L type bracket has certain inclination, and through the pneumatic stem shrink, stock material can the landing to the water conservancy diversion way in, and then falls on the transfer line.

Preferably, the telescopic rod and the bracket are symmetrically arranged on the base and respectively lift two ends of the anchor rod material.

Preferably, the base slides relative to the bracket via a guide rail.

Preferably, the lower end of the base is provided with a supporting leg.

By applying the technical scheme of the invention, the base is arranged; the first supporting plates are symmetrically arranged on the base in a matrix manner; the belt wheels are arranged between the first supporting plates and are positioned at two ends of the first supporting plates; the transmission belt is sleeved on the belt wheel and is provided with stop blocks arranged in a matrix manner; the rotating shaft is connected with the belt wheel, and one end of the rotating shaft is connected with a first motor; the telescopic rods are arranged on the base in a matrix manner, the upper ends of the telescopic rods are provided with brackets, and pneumatic rods are arranged on the brackets; the side surface of the bracket is provided with a guide rail which is matched with the base; the second supporting plates are arranged on the bracket in parallel in a matrix manner; the roll shafts are arranged between the second supporting plates in a matrix manner, one ends of the roll shafts are connected with chain wheels, and the end part chain wheels are connected with a second motor; the roller is sleeved on the roller shaft and positioned between the second supporting plates, and the roller forms a conveying line; the chain is annularly arranged on the chain wheel and matched with the chain wheel; the guide plates are arranged on the support, and a first guide plate, a second guide plate, a third guide plate, a fourth guide plate, a fifth guide plate and a shearing machine are sequentially arranged from one side close to the base to one side far away from the base. The synchronous shearing device has the advantages of reliable feeding, synchronous conveying of multiple materials and synchronous shearing.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 shows a schematic structural view of a rock bolt oblique head shearing device according to the invention;

fig. 2 shows a front view of the oblique head shearing device of the rock bolt of fig. 1;

fig. 3 shows a left side view of the oblique head shearing device of the rock bolt of fig. 1;

fig. 4 shows a right side view of the rock bolt oblique-head shearing device of fig. 1;

fig. 5 shows a top view of the rock bolt slant shear apparatus of fig. 1;

fig. 6 shows a bottom view of the oblique-head shear device of fig. 1;

fig. 7 shows an enlarged partial view of the oblique-head shear device of fig. 1.

Wherein the figures include the following reference numerals:

a first electric machine 1; a rotating shaft 2; a base 3; a transmission belt 4; a first support plate 5; a stopper 6; an anchor rod material 7; a guide rail 8; a second support plate 9; a support 10; a first guide plate 11; a second guide plate 12; a third guide plate 13; a fourth guide plate 14; a fifth guide plate 15; a shear 16; a stripper plate 17; a second motor 18; a roller 19; a chain 20; a sprocket 21; a pulley 22; a telescopic rod 23; a bracket 24; a pneumatic rod 25.

Detailed Description

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.

As shown in fig. 1 to 7, an embodiment of the present invention provides a shear device for a slant head of a rock bolt, including: a base 3; the first supporting plates 5 are symmetrically arranged on the base 3 in pairs in a matrix manner; pulleys 22 disposed between the first support plates 5 at both ends of the first support plates 5; the transmission belt 4 is sleeved on the belt wheel 22 and is provided with stop blocks 6 which are arranged in a matrix manner; the rotating shaft 2 is connected with the belt wheel 22, and one end of the rotating shaft is connected with the first motor 1; the telescopic rods 23 are arranged on the base 3 in a matrix manner, the upper ends of the telescopic rods are provided with brackets 24, and pneumatic rods 25 are arranged on the brackets 24; a bracket 10, the side surface of which is provided with a guide rail 8, wherein the guide rail 8 is matched with the base 3; the second supporting plates 9 are arranged on the bracket 10 in parallel in a matrix manner; the roll shafts are arranged between the second supporting plates 9 in a matrix manner, one ends of the roll shafts are connected with chain wheels 21, and the end part chain wheels 21 are connected with a second motor 18; the roller 19 is sleeved on the roller shaft and positioned between the second supporting plates 9, and the roller 19 forms a conveying line; the chain is annularly arranged on the chain wheel 21 and matched with the chain wheel 21; the guide plate is arranged on the bracket 10, and a first guide plate 11, a second guide plate 12, a third guide plate 13, a fourth guide plate 14 and a fifth guide plate 15 are sequentially arranged from one side close to the base 3 to one side far away from the base 3; and the shearing machine 16 is arranged at the end part of the bracket 10.

In this embodiment, the base 3; the base 3 slides relative to the bracket 10 via the guide rail 8. The lower end of the base 3 is provided with a supporting leg. The base 3 is provided for supporting purposes, and is used for supporting the first support plate 5 arranged in parallel and supporting the first telescopic rod 23 for supporting the motor. In this embodiment, the first supporting plates 5 are symmetrically arranged on the base 3 in a matrix; the first supporting plate 5 is arranged for supporting the belt wheel 22 shaft and the rotating shaft 2, further supporting the transmission belt 4 and further supporting the anchor rod material 7, the number of the first supporting plate 5 is at least six, the first supporting plate 5 is arranged in pairwise symmetry and is respectively arranged at the middle position and the two ends of the base 3 and is respectively used for supporting the two ends and the middle of the anchor rod material 7, and the first supporting plate 5 is connected with the belt wheel 22 shaft through a rotating bearing.

In this embodiment, the pulleys 22 are disposed between the first support plates 5 and located at both ends of the first support plates 5; the belt pulley 22 is arranged to drive the belt 4, and the belt pulley 22 is rotated by the shaft 2. In this embodiment, the transmission belt 4 is sleeved on the belt pulley 22, and the stop blocks 6 arranged in a matrix form are arranged on the transmission belt 4; the drive belt 4 sets up the purpose and supports and drive stock material 7, sets up dog 6 that the interval matrix set up, can make 7 intervals of stock material and tiling, guarantees the reliability of material loading quantity, lifts one by one through bracket 24, the many problem of overlapping of unloading of a transfer chain can not appear. 7 dog 6 intervals of stock material are laid on drive belt 4, the transfer chain parallel sets up side by side, and 7 both ends of stock material and middle lower extreme receive drive belt 4 respectively to support, and 4 quantity of drive belt include three at least, and pivot 2 links to each other with the band pulley 22 of every drive belt 4, links to each other through rolling bearing between pivot 2 and the first backup pad 5. The three transmission belts 4 synchronously transmit simultaneously, so that the transmission stability is ensured. The reliability of the transmission position is guaranteed by the cooperation of the transmission belt 4 and the stop block 6, accurate transmission can be guaranteed to be right above the bracket 24, and the anchor rod cannot deviate.

In this embodiment, the rotating shaft 2 is connected to the belt pulley 22, and one end of the rotating shaft is connected to the first motor 1. The first electric machine 1 is arranged to provide power for the transmission of the shaft 2. The shaft 2 is designed to rotate the pulley 22 and drive the belt 4 to move, so as to translate and convey the anchor rod material 7 to the position right above the bracket 24. First motor 1 drives pivot 2 and rotates, and pivot 2 drives band pulley 22 and rotates, and band pulley 22 drives drive belt 4 and rotates, and drive belt 4 drives dog 6 and removes, and drive belt 4 and dog 6 drive stock material 7 towards the transfer chain translation. Anchor rod material 7 is carried in the translation, carries the reliability higher, is favorable to carrying the accurate of quantity to be controlled.

In this embodiment, the telescopic rods 23 are arranged on the base 3 in a matrix form, the upper ends of the telescopic rods are provided with brackets 24, and the brackets 24 are provided with pneumatic rods 25; the telescopic link 23 includes first telescopic link 23, second telescopic link 23, third telescopic link 23, fourth telescopic link 23, first telescopic link 23 is located and is close to under 8 first stock materials 7 of guide rail, second telescopic link 23 is located and is close to under 8 second stock materials 7 of guide rail, third telescopic link 23 is located and is close to under 8 third stock materials 7 of guide rail, fourth telescopic link 23 is located and is close to under 8 fourth stock materials 7 of guide rail, every telescopic link 23 upper end all is equipped with L type bracket 24, the bracket 24 diaphragm is close to the edge and is equipped with pneumatic rod 25. Wherein the carriage 24 is also provided with an infrared emitter directed upwards, when simultaneously: when the infrared emitter of the first telescopic rod 23 is shielded once, the infrared emitter of the second telescopic rod 23 is shielded twice, the infrared emitter of the third telescopic rod 23 is shielded three times, and the infrared emitter of the fourth telescopic rod 23 is shielded four times, the information is transmitted to the controller, the controller controls the telescopic rods 23 to lift synchronously, each telescopic rod 23 rises for a certain distance to the diversion tunnel mouth, the controller controls all the pneumatic rods 25 to contract, under the action of gravity, the anchor rod materials 7 slide downwards along the bottom surface of the inclined bracket 24 and fall onto a conveying line formed by the conveying roller 19, synchronous conveying of the four anchor rod materials 7 to the shearing machine 16 is realized, the shearing machine 16 is provided with a blocking and aligning block, the bolts are aligned and then cut four at a time, four simultaneous cuts being made by a shear 16, wherein the shear 16 is provided with a hold down for hold down during cutting. The telescopic rod 23 drives the bracket 24 to ascend and descend, the bracket 24 supports the anchor rod material 7 to the road junction of the flow guide way, the transverse plate of the L-shaped bracket 24 has a certain inclination angle, and the anchor rod material 7 can slide into the flow guide way and further fall onto the conveying line after being contracted by the pneumatic rod 25. The telescopic rods 23 and the brackets 24 are symmetrically arranged on the base 3 and respectively lift two ends of the anchor rod material 7. First telescopic link 23 is used for lifting first stock material 7 near guide rail 8, and second telescopic link 23 is used for lifting second stock material 7 near guide rail 8, and third telescopic link 23 is used for lifting third stock material 7 near guide rail 8, and fourth telescopic link 23 is used for lifting fourth stock material 7 near guide rail 8. Through four telescopic links 23 and bracket 24, the accurate synchronous lift of stock can be guaranteed in setting up of infrared sensor and pneumatic stem 25, realize the synchronous unloading of many stocks, this patent is not limited to and only lifts four, can once cut quantity as required, design the device, increase drive belt 4 and water conservancy diversion way quantity and transfer chain quantity, and then can realize the reliable synchronous transport of more quantity stock material 7 and the cutting simultaneously of reliable synchronization.

In this embodiment, the bracket 10 has a guide rail 8 on the side, and the guide rail 8 is matched with the base 3; the support 10 is provided for the purpose of supporting the second support plate 9, the roll shaft, the second motor 18 and the like. In this embodiment, the second supporting plates 9 are arranged in parallel on the bracket 10 in a matrix; the second supporting plate 9 is arranged in a matrix for supporting the roller shafts, further supporting the roller wheels 19, further forming a plurality of roller wheel 19 conveying lines, synchronously conveying the anchor rod materials 7 at the same time, and the bracket 10 is further provided with a first guide plate 11, a second guide plate 12, a third guide plate 13 and a fourth guide plate 14, so that the anchor rod materials 7 can reliably enter the conveying lines.

In this embodiment, the roll shafts are arranged between the second support plates 9 in a matrix, one end of each roll shaft is connected with a chain wheel 21, and the chain wheel 21 at the end part is connected with the second motor 18; the roll shaft is used for supporting and driving the roll wheel 19 to rotate, the second motor 18 drives one of the chain wheels 21 to rotate, and then drives the chain 20 to transmit, the chain 20 drives other chain wheels 21 to rotate, the chain wheel 21 drives the roll shaft to rotate, the roll shaft drives the roll wheel 19 to rotate, and the roll wheel 19 drives the anchor rod material 7 to be conveyed towards the shearing machine 16. The second motor 18 provides transmission power to drive all the rollers 19 to synchronously transmit, so that synchronous conveying is realized at the same time.

In this embodiment, the rollers 19 are sleeved on the roller shafts and located between the second supporting plates 9, and the rollers 19 form a conveying line; the roller 19 realizes synchronous conveying of the anchor rod material 7 at the same time, and conveying reliability is guaranteed. In this embodiment, the chain is looped on the sprocket 21 and engaged with the sprocket 21; the chain is matched with the chain wheel 21 to realize the simultaneous synchronous transmission of all the roll shafts and the rollers 19. In the embodiment, the guide plates are arranged on the bracket 10, and a first guide plate 11, a second guide plate 12, a third guide plate 13, a fourth guide plate 14 and a fifth guide plate 15 are sequentially arranged from the side close to the base 3 to the side far away from the base 3; the guide plate is arranged to realize accurate entering of the anchor rod materials 7 into the conveying line, controllability and reliability of conveying quantity are guaranteed, and the problem that one conveying line falls into a plurality of anchor rod materials 7 is avoided. The first guide plate 11, the second guide plate 12, the third guide plate 13, the fourth guide plate 14 and the fifth guide plate 15 all comprise vertical parts and inclined parts, wherein the vertical parts of the first guide plate 11, the second guide plate 12, the third guide plate 13, the fourth guide plate 14 and the fifth guide plate 15 are sequentially increased in height, the lengths of the inclined parts are sequentially increased, a first guide way is formed between the first guide plate 11 and the second guide plate 12, a second guide way is formed between the second guide plate 12 and the third guide plate 13, a third guide way is formed between the third guide plate 13 and the fourth guide plate 14, a fourth guide way is formed between the fourth guide plate 14 and the fifth guide plate 15, the channel opening of the first guide way is positioned right above a first anchor rod 7 close to the guide rail 8, the channel opening of the second guide way is positioned right above a second anchor rod 7 close to the guide rail 8, and the channel opening of the third guide way is positioned right above a third anchor rod 7 close to the guide rail 8, and the opening of the fourth diversion channel is positioned right above the fourth anchor rod material 7 close to the guide rail 8. Can realize that every stock material 7 independently gets into respective transfer chain, synchronous reliable transmission simultaneously can realize continuous cycle transport, and four are a cycle circulation, and then continuous transport provides shearing efficiency. In this embodiment, the shear 16 is disposed at an end of the support 10. The shear 16 is independently arranged and used with a pressing device.

From the above description, it can be seen that the above-described embodiments of the present invention achieve the following technical effects: by arranging the base 3; the first supporting plates 5 are symmetrically arranged on the base 3 in a matrix manner; pulleys 22 provided between the first support plates 5 at both ends of the first support plates 5; the transmission belt 4 is sleeved on the belt wheel 22 and is provided with stop blocks 6 which are arranged in a matrix manner; the rotating shaft 2 is connected with the belt wheel 22, and one end of the rotating shaft is connected with the first motor 1; the telescopic rods 23 are arranged on the base 3 in a matrix manner, the upper ends of the telescopic rods are provided with brackets 24, and pneumatic rods 25 are arranged on the brackets 24; a bracket 10, the side surface of which is provided with a guide rail 8, wherein the guide rail 8 is matched with the base 3; the second supporting plates 9 are arranged on the bracket 10 in parallel in a matrix; the roll shafts are arranged between the second supporting plates 9 in a matrix manner, one ends of the roll shafts are connected with chain wheels 21, and the end part chain wheels 21 are connected with a second motor 18; the roller 19 is sleeved on the roller shaft and positioned between the second supporting plates 9, and the roller 19 forms a conveying line; the chain is annularly arranged on the chain wheel 21 and matched with the chain wheel 21; the guide plate is arranged on the bracket 10, a first guide plate 11, a second guide plate 12, a third guide plate 13, a fourth guide plate 14 and a fifth guide plate 15 are sequentially arranged from one side close to the base 3 to one side far away from the base 3, and the shearing machine 16 is arranged at the end part of the bracket 10. The synchronous shearing device has the advantages of reliable feeding, synchronous conveying of multiple materials and synchronous shearing.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. An anchor rod oblique head shearing device is characterized by comprising:

a base;

the first supporting plates are symmetrically arranged on the base in a matrix manner;

the belt wheels are arranged between the first supporting plates and are positioned at two ends of the first supporting plates;

the transmission belt is sleeved on the belt wheel and is provided with stop blocks arranged in a matrix manner;

the rotating shaft is connected with the belt wheel, and one end of the rotating shaft is connected with a first motor;

the telescopic rods are arranged on the base in a matrix manner, the upper ends of the telescopic rods are provided with brackets, and pneumatic rods are arranged on the brackets;

the side surface of the bracket is provided with a guide rail which is matched with the base;

the second supporting plates are arranged on the bracket in parallel in a matrix manner;

the roll shafts are arranged between the second supporting plates in a matrix manner, one ends of the roll shafts are connected with chain wheels, and the end part chain wheels are connected with a second motor; and

the roller is sleeved on the roller shaft and positioned between the second supporting plates, and the roller forms a conveying line;

the chain is annularly arranged on the chain wheel and matched with the chain wheel;

the guide plate is arranged on the support, and a first guide plate, a second guide plate, a third guide plate, a fourth guide plate and a fifth guide plate are sequentially arranged from one side close to the base to one side far away from the base;

and the shearing machine is arranged at the end part of the bracket.

2. The anchor rod oblique head shearing device of claim 1, wherein said first motor rotates a shaft, said shaft rotates a pulley, said pulley rotates a belt, said belt moves a dog, said belt and dog move the anchor rod material in translation toward the conveyor line.

3. The rock bolt slant head shearing apparatus of claim 1, wherein said second motor rotates one of the sprockets, thereby driving the chain, said chain driving the other sprockets, said sprocket driving the roller shaft, said roller shaft driving the roller wheel, said roller wheel driving the rock bolt material toward the shearing machine.

4. The oblique-head shearing device for the anchor rod according to claim 1, wherein the anchor rod material is laid on the transmission belt through the stop blocks at intervals, the transmission lines are arranged in parallel side by side, the two ends and the middle lower end of the anchor rod material are respectively supported by the transmission belt, the number of the transmission belts is at least three, the rotating shaft is connected with a belt wheel of each transmission belt, and the rotating shaft is connected with the first supporting plate through a rotating bearing.

5. The anchor rod oblique head shearing device according to claim 1, wherein the first guide plate, the second guide plate, the third guide plate, the fourth guide plate and the fifth guide plate each comprise a vertical part and an inclined part, wherein the vertical parts of the first guide plate, the second guide plate, the third guide plate, the fourth guide plate and the fifth guide plate sequentially increase in height, the length of the inclined parts sequentially increases, a first diversion tunnel is formed between the first guide plate and the second guide plate, a second diversion tunnel is formed between the second guide plate and the third guide plate, a third diversion tunnel is formed between the third guide plate and the fourth guide plate, a fourth diversion tunnel is formed between the fourth guide plate and the fifth guide plate, the crossing of the first diversion tunnel is positioned right above the first anchor rod material close to the guide rail, the crossing of the second diversion tunnel is positioned right above the second anchor rod material close to the guide rail, and the crossing of the third diversion tunnel is positioned right above the third anchor rod material close to the guide rail, and the opening of the fourth diversion channel is positioned right above the fourth anchor rod material close to the guide rail.

6. The anchor rod oblique head shearing device as claimed in claim 1, wherein the telescopic rods comprise a first telescopic rod, a second telescopic rod, a third telescopic rod and a fourth telescopic rod, the first telescopic rod is positioned under a first anchor rod material close to the guide rail, the second telescopic rod is positioned under a second anchor rod material close to the guide rail, the third telescopic rod is positioned under a third anchor rod material close to the guide rail, the fourth telescopic rod is positioned under a fourth anchor rod material close to the guide rail, an L-shaped bracket is arranged at the upper end of each telescopic rod, and a pneumatic rod is arranged on the transverse plate of each bracket close to the edge of the transverse plate.

7. The anchor rod oblique head shearing device as claimed in claim 1, wherein the telescopic rod drives the bracket to ascend and descend, the bracket supports the anchor rod material to the mouth of the flow guide channel, a transverse plate of the L-shaped bracket has a certain inclination angle, and the anchor rod material slides into the flow guide channel and then falls onto the conveying line by the contraction of the pneumatic rod.

8. The anchor rod oblique head shearing device as claimed in claim 1, wherein the telescopic rods and the brackets are symmetrically arranged on the base and respectively lift two ends of the anchor rod material.

9. The oblique-head shearing device for anchor rods according to claim 1, wherein the base slides relative to the bracket through the guide rails.

10. The oblique-head shearing device for anchor rods as claimed in claim 1, wherein the lower end of the base is provided with a supporting leg.

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