CN220077657U - Automatic short pipe feeding mechanism for IBC ton bucket processing - Google Patents

Abstract

The utility model relates to an automatic short pipe feeding mechanism for IBC ton barrel processing, which sequentially comprises a storage bin, a feeding chain, a transition frame, a material moving assembly and a discharging frame, wherein a bottom plate of the storage bin is inclined downwards towards one end of a discharge hole of the storage bin; the feeding chain is arranged at a discharge hole of the storage bin, and a feeding block is arranged on the feeding chain; the transition frame is inclined upwards towards one end of the feeding chain; the material moving assembly comprises two fixed material moving plates which are oppositely arranged, and a movable material moving plate which is arranged in the fixed material moving plates and can swing back and forth; a plurality of groups of discharging blocks are arranged above the discharging frame; the feeding chain rotates to drive the feeding block to pick up the pipe from the storage bin and put the pipe on the transition frame, the pipe falls from the transition frame to the material moving assembly, and the material moving assembly moves the pipe to the material discharging frame. The full-automatic feeding device can rapidly realize full-automatic feeding of the pipe required by the outer frame of the ton barrel, and effectively improves the feeding efficiency and the processing efficiency of the ton barrel.

Description

Automatic short pipe feeding mechanism for IBC ton bucket processing

Technical Field

The utility model belongs to the technical field of ton bucket production, and particularly relates to an automatic short pipe feeding mechanism for IBC ton bucket processing.

Background

The IBC ton barrel has the advantages of light weight, high strength, corrosion resistance and the like, is widely applied to industries such as chemical industry, medicine, food, paint and the like, and is a necessary tool for modern storage and transportation of liquid products. The ton bucket is assembled by the inner container, inner bag and outside metal frame, and wherein the inner bag adopts the high polymer high density polyethylene blow molding, and intensity is high, corrosion-resistant, the sanitation is good, and the outside cover of inner bag then can make ton bucket safe and reliable more in the use.

The metal outer frame of ton bucket is by many tubular product through the amalgamation welding, and current metal outer frame is when processing, and tubular product all adopts the mode of single material loading, but because tubular product quantity is more, this kind of material loading mode is very consuming time, and is inefficiency, directly influences the machining efficiency of ton bucket moreover.

Disclosure of Invention

The utility model aims to provide a short pipe automatic feeding mechanism for IBC ton barrel processing, which aims to solve the problem of pipe feeding efficiency.

The utility model discloses an automatic feeding mechanism for short pipe materials for processing IBC ton barrels, which is realized by the following steps:

automatic short pipe feeding mechanism for IBC ton bucket processing includes in proper order

The bottom plate of the storage bin is inclined downwards towards one end of the discharge hole of the storage bin;

the feeding chain is arranged at the discharge hole of the storage bin, and a feeding block is arranged on the feeding chain;

the transition frame is inclined upwards towards one end of the feeding chain;

the material moving assembly comprises two fixed material moving plates which are oppositely arranged, and a movable material moving plate which is arranged in the fixed material moving plates and can swing back and forth;

a plurality of groups of discharging blocks are arranged above the discharging frame;

the feeding chain rotates to drive the feeding block to pick up the pipe from the storage bin and put the pipe on the transition frame, the pipe falls from the transition frame to the material moving assembly, and the material moving assembly moves the pipe to the material discharging frame.

Further, a discharge hole of the storage bin is positioned at the front end of the storage bin, a support shaft is arranged at the front side below the storage bin, and the bottom plate can rotate relative to the support shaft;

the rear side below the storage bin is provided with a lifting cylinder, and the top of a piston rod of the lifting cylinder is connected with the rear end of the bottom plate.

Further, the feeding chains are provided with at least two feeding chains and are arranged at the discharge port of the storage bin;

the front side of the bin is provided with two sprocket shafts which are arranged up and down, and the feeding chains are respectively assembled on corresponding sprockets of the two sprocket shafts;

the feeding motor is arranged below the storage bin and is in transmission connection with one of the chain wheel shafts.

Further, a material picking groove is formed in the material feeding block.

Further, the rear end of the transition frame is arranged side by side with the feeding chain, and the front end faces the material moving assembly;

one side of the front end of the transition frame is provided with a striker plate, and the other side of the front end of the transition frame is provided with a lifting plate capable of lifting;

and a limiting cover plate is arranged above the transition frame.

Further, the method comprises the steps of,

the upper edge of fixed material moving plate is provided with a plurality of material moving grooves I, the upper edge of movable material moving plate is provided with a material moving groove II corresponding to the material moving groove I.

Further, a material moving motor is arranged between the two movable material moving plates, the output end of the material moving motor is connected with a cam, the cam is connected with the material moving plates, the material moving plates are connected with a material moving frame, and the two movable material moving plates are respectively arranged at two ends of the material moving frame.

Further, one of them fixed flitch outside is provided with the detection axle that moves the silo I relative with one of them, the outside of detection axle is provided with the drive the flexible detection cylinder of detection axle.

Further, two conveying belts which are arranged in parallel are arranged on the discharging frame, and the discharging block is fixed on the conveying belts;

the driving belt wheel of the conveying belt is positioned at the front side of the discharging frame, the outer side of the driving belt wheel of one conveying belt is connected with a conveying motor, and the two driving belt wheels are connected through a synchronous shaft.

Further, the outside of two conveyer belts is installed the material pushing block of relative setting, the outside of material pushing block is installed and is driven the material pushing cylinder of material pushing block removal.

After the technical scheme is adopted, the utility model has the following beneficial effects:

according to the utility model, through picking, transferring and placing the pipes, full-automatic and disposable feeding of the pipes required by the outer frame of the ton barrel can be realized rapidly, time and labor are saved, and the feeding efficiency and the processing efficiency of the ton barrel are improved effectively.

Drawings

The utility model will be further described with reference to the drawings and examples.

FIG. 1 is a block diagram of a short pipe automatic feeding mechanism for IBC ton barrel processing according to a preferred embodiment of the present utility model;

FIG. 2 is a block diagram of a short pipe automatic feeding mechanism (not loaded with a charging rack) for IBC ton barrel processing according to a preferred embodiment of the present utility model;

FIG. 3 is a block diagram of a short pipe automatic feeding mechanism (not loaded with a charging rack) for IBC ton barrel processing according to a preferred embodiment of the present utility model;

FIG. 4 is an enlarged view of portion A of FIG. 3;

in the figure: the material feeding device comprises a material bin 1, a material feeding chain 2, a transition frame 3, a material discharging frame 4, a bottom plate 5, a material feeding block 6, a fixed material moving plate 7, a movable material moving plate 8, a material discharging block 9, a material bin side plate 10, a material bin front baffle 11, a waist-shaped hole 12, a supporting shaft 13, a material bin bracket 14, a connecting plate 15, a lifting cylinder 16, a transition plate 17, a chain wheel shaft 18, a material feeding motor 19, a material picking groove 20, a material blocking plate 21, a material ejecting plate 22, a material ejecting cylinder 23, a limiting cover plate 24, a material moving bracket 25, a bracket side plate 26, a material moving groove I27, a material moving groove II 28, a material moving motor 29, a cam 30, a material moving frame 31, a material moving frame 32, a detection shaft 33, a detection cylinder 34, a conveying belt 35, a conveying motor 36, a synchronous shaft 37, a material pushing block 38, a material pushing cylinder 39 and a pipe 40.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

As shown in fig. 1-4, the automatic feeding mechanism for the short pipe materials for processing the IBC ton barrel sequentially comprises a feed bin 1, a feeding chain 2, a transition frame 3, a material moving assembly and a discharging frame 4, wherein a bottom plate 5 of the feed bin 1 is inclined downwards towards one end of a discharge hole of the feed bin 1; the feeding chain 2 is arranged at the discharge hole of the storage bin 1, and a feeding block 6 is arranged on the feeding chain 2; the transition frame 3 is inclined upwards towards one end of the feeding chain 2; the material moving assembly comprises two fixed material moving plates 7 which are oppositely arranged, and a movable material moving plate 8 which is arranged in the fixed material moving plates 7 and can swing back and forth; a plurality of groups of discharging blocks 9 are arranged above the discharging frame 4; the feeding chain 2 rotates to drive the feeding block 6 to pick up the pipe 40 from the storage bin 1 and put the pipe 40 on the transition frame 3, the pipe 40 falls to the material moving assembly from the transition frame 3, and the material moving assembly moves the pipe 40 to the material discharging frame 4.

The feed bin 1, the feeding chain 2, the transition frame 3, the material moving assembly and the discharging frame 4 are sequentially arranged from back to front, and the pipe 40 is sequentially transferred onto the discharging frame 4 from the feed bin 1 through the feeding chain 2, the transition frame 3 and the material moving assembly.

The feed bin 1 is arranged on a feed bin bracket 14, and comprises two feed bin side plates 10 and a feed bin front baffle 11 positioned above a discharge hole, wherein the rear side of the feed bin 1 is provided with an opening, so that a pipe 40 is conveniently added into the feed bin 1. Preferably, the bin side plate 10 is provided with an arc-shaped waist-shaped hole 12, and the inclination angle of the bin front baffle 11 can be adjusted through the waist-shaped hole 12.

The bottom plate 5 of the feed bin 1 that the slope set up can make things convenient for tubular product 40 to slide to the discharge gate department of feed bin 1 under the effect of gravity, and the material loading piece 6 on the material loading chain 2 of being convenient for picks up tubular product 40, and for the inclination of convenient regulation bottom plate 5, the discharge gate of feed bin 1 is located its front end, and the front side of feed bin 1 below is provided with back shaft 13, and bottom plate 5 can rotate relative back shaft 13.

The two ends of the supporting shaft 13 are fixed on the bin bracket 14 through bearings, while the two sides of the bottom plate 5 are matched on the supporting shaft 13 through connecting plates 15 which extend downwards and are provided with bayonets, namely the bayonets are clamped on the supporting shaft 13, and the bottom plate 5 can rotate by an inclined angle relative to the supporting shaft 13.

In order to power the angle adjustment of the bottom plate 5, a lifting cylinder 16 is arranged at the rear side below the storage bin 1, and the top of a piston rod of the lifting cylinder 16 is connected with the rear end of the bottom plate 5.

The bottom of lifting cylinder 16 is installed on feed bin support 14 through articulated seat down, and the top of its piston rod links to each other with bottom plate 5 through articulated seat down, through the flexible of piston rod, cooperates back shaft 13, realizes bottom plate 5 inclination's adjustment.

Preferably, the front end of the bottom plate 5 is provided with a transition plate 17 which is matched with the bottom plate and is obliquely arranged, and two ends of the front side of the transition plate 17 are provided with avoiding notches which are matched with the feeding chain 2.

The pipe 40 placed in the storage bin 1 slides towards the direction of the discharge hole of the storage bin and then falls onto the transition plate 17, and at the moment, the pipe 40 can be picked up by the feeding block 6 passing through the avoidance gap, and then the pipe 40 is conveyed forward.

In order to be able to take out the pipe 40 from the discharge opening of the silo 1, the feed chain 2 is provided with at least two and is arranged side by side at the discharge opening of the silo 1.

In this embodiment, two feeding chains 2 are provided, so that stability of the pipe 40 on the feeding chains 2 can be ensured.

In order to realize the installation of the feeding chain 2, the front side of the bin 1 is provided with two sprocket shafts 18 arranged up and down, and the feeding chain 2 is respectively assembled on corresponding sprockets of the two sprocket shafts 18.

Specifically, two sprocket shafts 18 are arranged in parallel, two ends of the two sprocket shafts are respectively mounted on the bin bracket 14 through bearings, the positions, close to the ends, of each sprocket shaft 18 are respectively provided with a sprocket, the same feeding chain 2 is assembled on the two sprockets on the same side of the two sprocket shafts 18, and the rotation of the sprocket shafts 18 drives the feeding chain 2 to rotate and the feeding block 6 to move.

In order to provide power for the rotation of the feeding chain 2, a feeding motor 19 is arranged below the storage bin 1, and the feeding motor 19 is in transmission connection with one of the sprocket shafts 18.

The feeding motor 19 is fixed on the bin bracket 14 through a motor seat, a driving sprocket is mounted on an output shaft of the feeding motor, a driven sprocket is mounted on a sprocket shaft 18 positioned below the feeding motor, the driving sprocket and the driven sprocket are connected through a transmission chain (not shown in the figure), and the feeding motor 19 can drive the lower sprocket shaft 18 to rotate, so that the upper sprocket shaft 18 is matched to realize the rotation of the feeding chain 2.

In order to facilitate the picking up of the pipe 40, the pick-up chute 20 is provided on the loading block 6.

Specifically, the outer chain link of the feeding chain 2 is provided with an outwardly extending mounting plate, and the feeding block 6 is fixed on the mounting plate.

Preferably, the pick-up groove 20 is an arc groove, and the opening of the pick-up groove 20 facing to one side of the bin 1 is upward, so that the pipe 40 can be stably placed in the pick-up groove 20.

In order to facilitate the transfer of the pipe 40 from the feed chain 2 to the transfer assembly, the rear end of the transition frame 3 is arranged side by side with the feed chain 2, with the front end facing the transfer assembly.

The feeding block 6 moves upwards towards one side of the storage bin 1 under the drive of the sprocket shaft 18, so that the pipe 40 is driven to rise, when the feeding block 6 passes through the sprocket above, the pick-up groove 20 turns over, namely, the opening faces downwards, and the pipe 40 in the pick-up groove 20 directly falls onto the transition frame 3, so that the pipe falls onto the material moving assembly along the inclined transition frame 3.

In this embodiment, the transition frame 3 is provided with two and arranged side by side, and is located outside the two feeding chains 2, respectively.

In order to control the pipe 40 on the transition frame 3, one side of the front end of the transition frame 3 is provided with a baffle 21, and the other side is provided with a lifting top plate 22.

Wherein, the striker plate 21 is used for stopping the tubular product 40 on the transition frame 3 from sliding off at will, and the setting of liftout plate 22 can raise tubular product 40 that is located the front side on the transition frame 3 one by one, makes it be higher than striker plate 21, then falls to the material subassembly that moves.

Specifically, the striker plate 21 is disposed outside the front end of the transition frame 3, the ejector plate 22 is disposed inside the front end of the transition frame 3, and an ejector cylinder 23 for driving the ejector plate to lift is disposed below the striker plate, and the lifter plate 22 is driven to lift by the expansion and contraction of a piston rod of the ejector cylinder 23.

Preferably, the upper edges of the baffle 21 and the ejector 22 are inclined downwards at the front side, so that the pipe 40 can conveniently fall onto the material moving assembly after being attached to the upper edges of the baffle and the ejector.

In order to avoid multi-layer accumulation of the pipes 40 on the transition frame 3, a limit cover plate 24 is arranged above the transition frame 3.

The material moving assembly is arranged on a material moving support 25, the material moving support 25 is connected with the stock bin support 14, and support side plates 26 are arranged on two sides of the material moving support 25.

Wherein, the fixed material moving plate 7 is arranged on the material moving bracket 25, and the movable material moving plate 8 is arranged on the inner side of the fixed material moving plate 7.

In order to realize gradual forward movement of the pipe 40 on the material moving assembly, a plurality of material moving grooves I27 are formed in the upper edge of the fixed material moving plate 7, and a material moving groove II 28 corresponding to the material moving grooves I27 is formed in the upper edge of the movable material moving plate 8.

When the movable material moving plate 8 swings to the rearmost side, the material moving grooves II 28 and the material moving grooves I27 are arranged in one-to-one correspondence, and when the movable material moving plate 8 swings to the foremost side, the material moving grooves II 28 are opposite to the previous material moving groove I27, so that the pipe 40 in the material moving groove I27 can be continuously moved forwards until being moved to the discharging frame 4 through the swing of the movable material moving plate 8.

The stroke of the movable material moving plate 8 swinging back and forth is the distance between two adjacent material moving grooves on the same material moving plate.

In order to realize the forward and backward swing of the movable material moving plates 8, a material moving motor 29 is arranged between the two movable material moving plates 8, the output end of the material moving motor 29 is connected with a cam 30, a material moving frame 31 is connected to the cam 30, the material moving frame 31 is connected with a material moving frame 32, and the two movable material moving plates 8 are respectively arranged at two ends of the material moving frame 32.

The material moving motor 29 is fixed on the material moving bracket 25 through the motor seat II, an output shaft of the material moving motor is connected with a protruding part of the cam 30, the center of the cam 30 is connected with the material moving frame 31, the material moving motor 29 rotates for one circle, the movable material moving plate 8 can be driven to swing back and forth once, namely, the movable material moving plate 8 moves forward and upward when swinging forward, the pipe 40 on the fixed material moving plate 7 can be moved forward, and the pipe 40 on the fixed material moving plate 7 can be prevented from touching the pipe 40 on the fixed material moving plate 7 when swinging backward.

The moving frame 32 includes two cross bars installed above the moving frame 31, and end plates provided at both ends of the cross bars, and the movable moving plate 8 is installed above the end plates.

Preferably, the outside of end plate installs vertical slider and horizontal linear guide, and wherein vertical slider and the vertical linear guide cooperation of setting on moving material support 25, and horizontal linear guide then with install on moving material support 25 and be the slider cooperation that transversely sets up, through the cooperation of two kinds of sliders and linear guide, can lead the back-and-forth swing of movable material board 8.

Preferably, a cover plate (not shown) is arranged on the material moving frame 32, so that the structure of the material moving motor 29 and the like can be protected.

The both ends of tubular product 40 are the flat structure that has the arc wall, and its arc wall is placed up when putting on blowing frame 4, in order to detect the direction of tubular product 40, the outside of one of them fixed flitch 7 that moves is provided with the detection axle 33 that moves the silo I27 relatively with one of them, and the outside of detection axle 33 is provided with the detection cylinder 34 that can drive it inwards or outwards to remove.

The detection shaft 33 is positioned near the front end of the material moving assembly, and when the pipe 40 is in the correct direction, namely the arc-shaped groove is upward, the detection shaft 33 can directly extend into the arc-shaped groove; if the direction of the pipe 40 is wrong, the pipe 40 will block the movement of the detecting shaft 33, so as to push the pipe 40, and at this time, the pipe 40 with wrong direction can be removed from the material moving assembly.

The discharging frame 4 is arranged at the front side of the material moving bracket 25, and the material moving groove II 28 at the forefront side of the movable material moving plate 8 can move the tubes 40 positioned on the forefront material moving groove I27 to the discharging blocks 9 one by one.

In order to place the tubes 40 one by one on the discharge rack 4, two parallel conveyor belts 35 are arranged on the discharge rack 4, and the discharge blocks 9 are fixed on the conveyor belts 35.

The discharging block 9 is provided with a U-shaped groove, so that the pipe 40 can be conveniently placed.

In order to realize the rotation of the conveyer belt 35, the driving pulleys of the conveyer belt 35 are positioned at the front side of the discharging frame 4, the outer side of the driving pulley of one conveyer belt 35 is connected with a conveyer motor 36, and the two driving pulleys are connected through a synchronizing shaft 37

The conveyor motor 36 rotates the two driving pulleys, thereby effecting movement of the two conveyor belts 35.

Preferably, the front sides of the driven pulleys of the two conveyor belts 35 are respectively provided with a conveyor belt tensioning mechanism for tensioning adjustment of the conveyor belts 35.

Preferably, a dust cover (not shown) is mounted on the conveying motor 36 to realize dust protection of the conveying motor 36.

In order to align the two ends of the pipe 40 on the discharging frame 4, the outer sides of the two conveying belts 35 are provided with oppositely arranged pushing blocks 38, and the outer sides of the pushing blocks 38 are provided with pushing cylinders 39 for driving the pushing blocks 38 to move.

When the pipe 40 moves between the two pushing blocks 38 under the driving of the conveyor belt 35, the two pushing blocks 38 move toward each other under the action of the pushing cylinder 39, so that the two ends of the pipe 40 are aligned in a limiting manner, and the ends of each pipe 40 are aligned.

When the pipe 40 is fed, the pipe 40 is placed in the bin 1, the feeding chain 2 is utilized to drive the feeding block 6 to pass through a discharge hole of the bin 1, so that the pipe 40 is picked up and lifted, the pipe 40 falls on the transition frame 3 one by one and falls on the material moving assembly through the transition frame 3, the pipe 40 is finally transferred to the discharging frame 4 through the forward movement of the material moving assembly, and when the number of the pipes 40 placed on the discharging frame 4 reaches the number required by an outer frame, the pipe 40 can be removed at one time by utilizing the pipe 40 grabbing equipment, the full-automatic and one-time feeding of the pipe 40 is realized, and the feeding efficiency and the processing efficiency of the ton barrel are effectively improved.

With the above-described preferred embodiments according to the present utility model as an illustration, the above-described descriptions can be used by persons skilled in the relevant art to make various changes and modifications without departing from the scope of the technical idea of the present utility model. The technical scope of the present utility model is not limited to the description, but must be determined according to the scope of claims.

Claims (10)

1. Automatic short pipe feeding mechanism for IBC ton bucket processing, which is characterized by comprising the following components in sequence

The bottom plate (5) of the storage bin (1) is inclined downwards towards one end of a discharge hole of the storage bin (1);

the feeding chain (2) is arranged at the discharge hole of the storage bin (1), and a feeding block (6) is arranged on the feeding chain (2);

the transition frame (3) is inclined upwards towards one end of the feeding chain (2);

the material moving assembly comprises two fixed material moving plates (7) which are oppositely arranged, and a movable material moving plate (8) which is arranged in the fixed material moving plates (7) and can swing back and forth;

a plurality of groups of discharging blocks (9) are arranged above the discharging frame (4);

the feeding chain (2) rotates to drive the feeding block (6) to pick up the pipe from the storage bin (1) and put the pipe on the transition frame (3), the pipe falls to the material moving assembly from the transition frame (3), and the material moving assembly moves the pipe to the discharging frame (4).

2. The automatic feeding mechanism for short pipe materials for IBC ton bucket processing according to claim 1, wherein the discharging port of the bin (1) is positioned at the front end of the discharging port, a supporting shaft (13) is arranged at the front side below the bin (1), and the bottom plate (5) can rotate relative to the supporting shaft (13);

the rear side below the storage bin (1) is provided with a lifting air cylinder (16), and the top of a piston rod of the lifting air cylinder (16) is connected with the rear end of the bottom plate (5).

3. The automatic feeding mechanism for short pipe materials for IBC ton bucket processing according to claim 1, wherein at least two feeding chains (2) are arranged and arranged at the discharge hole of the stock bin (1);

the front side of the bin (1) is provided with two sprocket shafts (18) which are arranged up and down, and the feeding chain (2) is respectively assembled on corresponding sprockets of the two sprocket shafts (18);

the feeding motor (19) is arranged below the storage bin (1), and the feeding motor (19) is in transmission connection with one of the chain wheel shafts (18).

4. The automatic feeding mechanism for short pipe materials for IBC ton bucket processing according to claim 1, characterized in that the feeding block (6) is provided with a pick-up groove (20).

5. The automatic feeding mechanism for short pipe materials for IBC ton barrel processing according to claim 1, characterized in that the rear end of the transition frame (3) is arranged side by side with the feeding chain (2), and the front end faces the material moving assembly;

one side of the front end of the transition frame (3) is provided with a striker plate (21), and the other side is provided with a lifting ejector plate (22);

a limiting cover plate (24) is arranged above the transition frame (3).

6. The automatic feeding mechanism for short pipe materials for IBC ton barrel processing according to claim 1, wherein,

the upper edge of the fixed material moving plate (7) is provided with a plurality of material moving grooves I (27), and the upper edge of the movable material moving plate (8) is provided with a material moving groove II (28) corresponding to the material moving grooves I (27).

7. The automatic feeding mechanism for short pipe materials for IBC ton bucket processing according to claim 1, characterized in that a material moving motor (29) is arranged between two movable material moving plates (8), the output end of the material moving motor (29) is connected with a cam (30), the cam (30) is connected with a material moving frame (31), the material moving frame (31) is connected with a material moving frame (32), and the two movable material moving plates (8) are respectively arranged at two ends of the material moving frame (32).

8. The automatic feeding mechanism for short pipe materials for IBC ton bucket processing according to claim 6, characterized in that a detection shaft (33) opposite to one of the material moving grooves i (27) is arranged on the outer side of one of the fixed material moving plates (7), and a detection cylinder (34) driving the detection shaft (33) to stretch and retract is arranged on the outer side of the detection shaft (33).

9. The automatic feeding mechanism for short pipe materials for IBC ton bucket processing according to claim 1, characterized in that two parallel arranged conveyor belts (35) are arranged on the discharging frame (4), and the discharging block (9) is fixed on the conveyor belts (35);

the driving belt wheels of the conveying belts (35) are located on the front side of the discharging frame (4), the outer side of the driving belt wheel of one conveying belt (35) is connected with a conveying motor (36), and the two driving belt wheels are connected through a synchronous shaft (37).

10. The automatic feeding mechanism for short pipe materials for IBC ton barrel processing according to claim 9, characterized in that the outer sides of the two conveying belts (35) are provided with oppositely arranged pushing blocks (38), and the outer sides of the pushing blocks (38) are provided with pushing cylinders (39) for driving the pushing blocks (38) to move.