CN217534187U - Pipe feeding system - Google Patents

Abstract

The utility model discloses a tubular product feeding system, its technical scheme main points are including the feed stack device, conveyor, feed divider and transfer device, transfer device and feed stack device set up respectively in conveyor's both sides, the feed stack device is including bounding wall and a plurality of support frame, conveyor is including the carriage, a plurality of groups conveying chain and pay-off area and feed table, the one end and the pay-off table of feed table coiling of feed table are connected, the other end is put the frame with supporting and is connected, when the pay-off table drives the tubular product roll to the conveying chain on the feed table when straightening, when this tubular product feeding system can improve work efficiency, need not artifical the intervention, realize efficient automation work flow.

Description

Pipe feeding system

Technical Field

The utility model relates to a feeding system, more specifically say, it relates to a tubular product feeding system.

Background

The pipe feeding system is a feeding device used for transferring circular pipes, and before the pipes are cut, the pipes need to be conveyed to a cutting machine through a pipe feeding and feeding device. But the existing pipe material loading and conveying processes are complicated to operate and generally need manual intervention and adjustment, so that not only is the manpower resource wasted, but also the working efficiency is low.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims to provide a tubular product feeding system, this tubular product feeding system need not artifical the intervention when can improve work efficiency, realizes the automatic work flow of efficient.

In order to achieve the above purpose, the utility model provides a following technical scheme: a pipe feeding system comprises a material stack device, a conveying device, a material distribution device and a transfer device, wherein the transfer device and the material stack device are respectively arranged on two sides of the conveying device, and the material stack device comprises a surrounding plate and a plurality of bearing frames;

the conveying device comprises a conveying frame, a plurality of groups of conveying chains, a feeding belt and a feeding plate, one end of the feeding belt is connected with the feeding plate in a winding mode, the other end of the feeding belt is connected with the bearing frame, and when the feeding plate drives the feeding belt to be straightened, the pipes on the feeding belt roll onto the conveying chains.

To sum up, the utility model discloses following beneficial effect has: put into the tubular product and cut apart the binding rope in the feed stack device, wait for the material loading, the pay-off area is located the below of tubular product this moment, starts the rolling pay-off area as the pay-off dish, along with the continuous slope of pay-off area and rising for the tubular product that is located on the pay-off area arranges the roll by oneself, until roll in proper order on the conveying chain, carry it to feed divider position department by the conveying chain, divide the material operation, will divide the single tube after the material afterwards to remove to the cutting position through transfer device.

Because this pay-off area can form optimum angle through the drive of pay-off dish in the feed stack to can all tubular products homoenergetic shifts to the carriage, accomplish the high-efficient transfer, improve transfer rate, through subsequent branch material, shift moreover, can realize full-automatic tubular product and shift the operation, need not artificial intervention, improve work efficiency greatly.

Drawings

FIG. 1 is a schematic perspective view of a pipe feeding system;

FIG. 2 is a schematic perspective view of a second view of the tube feeding system;

FIG. 3 is an enlarged view of the point A in FIG. 1;

FIG. 4 is a schematic perspective view of the material separating device;

fig. 5 is a schematic perspective view of the transfer device.

Reference numerals: 1. a material stack device; 11. enclosing plates; 12. a bearing frame; 2. a conveying device; 21. a carriage; 22. a conveyor chain; 23. a feed belt; 24. a feed tray; 25. a synchronization component; 251. a synchronous motor; 252. A synchronizing shaft; 253. a synchronization chain; 254. a driving wheel; 255. a driven wheel; 256. a linkage shaft; 3. a material distributing device; 31. a mounting seat; 32. a drive member; 33. a limiting plate; 34. a limiting part; 35. a receiving part; 36. A blocking portion; 37. a guide ramp; 4. a transfer device; 41. a transfer seat; 42. a clamping seat; 43. an upper clamping arm; 44. a lower clamping arm; 45. a clamp driver; 46. the anti-falling edge; 5. a first guide rail; 51. a first slider.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. In which like parts are designated by like reference numerals. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "bottom" and "top," "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

Referring to fig. 1 to 5, in order to achieve the above object, the present invention provides the following technical solutions: a pipe feeding system comprises a material stack device 1, a conveying device 2, a material distribution device 3 and a transfer device 4, wherein the transfer device 4 and the material stack device 1 are respectively arranged on two sides of the conveying device 2, and the material stack device 1 comprises a coaming 11 and a plurality of bearing frames 12;

the conveying device 2 comprises a conveying frame 21, a plurality of groups of conveying chains 22, a feeding belt 23 and a feeding tray 24, one end of the feeding belt 23 is connected with the feeding tray 24 in a winding mode, the other end of the feeding belt 23 is connected with the bearing frame 12, and when the feeding tray 24 drives the feeding belt 23 to be straightened, the pipes on the feeding belt 23 roll onto the conveying chains 22.

The utility model discloses a design, put into tubular product and cut open and bind the rope in the stack device 1, wait for the material loading, feeding belt 23 is located the below of tubular product this moment, start rolling feeding belt 23 when feed table 24, along with feeding belt 23's continuous slope and rising, make the tubular product that is located on feeding belt 23 arrange the roll by oneself, until roll in proper order to conveying chain 22 on, carry it to 3 position departments of feed divider by conveying chain 22, divide the material operation, the single tube after will dividing the material afterwards passes through transfer device 4 and removes to the cutting position.

Because this pay-off area 23 can form optimum angle through the drive of pay-off dish 24 in the feed stack to can all tubular products homoenergetic enough shift to carriage 21, accomplish the high-efficient transfer, improve transfer rate, through subsequent branch material, shift moreover, can realize full-automatic tubular product and shift the operation, need not artificial intervention, improve work efficiency greatly.

The feeding belt 23 adopts a flat hanging strip, and the flat hanging strip has the following advantages:

1. the bearing surface is wide, so that the pressure of surface load can be reduced;

2. when the outer surface of the flat sling is smooth and fine, the hung object can not be damaged;

3. the cable is not conductive and has no electric shock hazard;

4. the elastic elongation of the flat sling is less than or equal to 7 percent.

The bearing frame 12 is arranged in an L-shaped structure, one end of the feeding belt 23 is connected with the upper end of the bearing frame 12, the height position of the feeding tray 24 is lower than that of the upper end of the bearing frame 12, and the height position of the feeding tray 24 is higher than that of the conveying chain 22. The feeding belt 23 forms an inclined plane inclined from the high end to the low end, and the pipe on the feeding belt 23 rolls down onto the conveying frame 21.

As shown in fig. 1, the shroud 11 and the adapter form a storage cavity for the tubing.

The conveying device 2 comprises a synchronizing part 25 which drives a plurality of groups of conveying chains 22 to synchronously rotate, the synchronizing part 25 comprises a synchronizing motor 251, a synchronizing shaft 252 and a plurality of groups of driving parts, and the driving parts comprise a synchronizing chain 253, a driving wheel 254, a driven wheel 255 and a linkage shaft 256;

the synchronous motor 251 is used for driving the synchronous shaft 252 to rotate, and the synchronous shaft 252 is connected with the driving wheel 254;

the driving wheel 254 is connected with the synchronous chain 253;

the driven wheel 255 is connected with the conveying chain 22 through a linkage shaft 256.

The material distributing device 3 comprises a mounting seat 31, a driving piece 32 and a limiting plate 33;

the limiting plate 33 includes a limiting portion 34 and a receiving portion 35 disposed at the top end, and a blocking portion 36, the limiting portion 34 and the blocking portion 36 are disposed at two sides of the receiving portion 35, respectively, the height position of the limiting portion 34 is higher than that of the receiving portion 35, and the limiting portion 34 is provided with a guiding inclined surface 37.

The driving member 32 includes a driving motor and a driving gear, and the limiting plate 33 is provided with a rack engaged with the driving gear.

Carry out unified transport operation to tubular product through conveying chain 22, rethread driving piece 32 makes limiting plate 33 rise, make spacing portion 34 remove to tubular product the place ahead, block advancing of tubular product, conveying chain 22 stops moving this moment, driving piece 32 drive limiting plate 33 descends afterwards, conveying chain 22 drives tubular product forward movement one work unit (according to the tubular product size, adjust the distance of self movement unit again), later driving piece 32 drive limiting plate 33 rises, guide inclined plane 37 inserts from between two tubular products this moment, make the tubular product in the place ahead along with guide inclined plane 37 to the direction of accepting 35, the tubular product in the place ahead is blocked by spacing portion 34 once more, the separation operation of single tube and follow-up tubular product is accomplished to the single tube in the place ahead and 36 butt of stopping portion, this limiting plate 33 at last continues to rise, make tubular product remove to the clamping part can the clamping area in, until being shifted by the clamping part centre gripping.

Therefore, stable single-pipe separation, transfer and other operations can be realized through the matching of the material distribution device 3 and the clamping piece, and the situation of multi-pipe movement can be effectively avoided in the non-movement process of the conveying chain 22.

The transfer device 4 comprises a transfer base 41 and a clamping base 42 connected to the transfer base 41 in a sliding manner, wherein an upper clamping arm 43 and a lower clamping arm 44 and a clamping driver 45 are arranged on the clamping base 42.

The clamping arms and the end of the lower clamping arm 44 away from the clamping seat 42 are both provided with a retaining edge 46 in a detachable mode. Due to the design of the anti-falling edge 46, the upper clamping arm 43, the lower clamping arm 44 and the anti-falling edge 46 form a closed loop, and the pipe can be effectively limited.

Two anticreeps along 46 butt earlier in last centre gripping arm 43 and lower centre gripping arm 44 centre gripping process to form the centre gripping chamber in certain space, according to the size specification of tubular product, adjust two anticreeps along 46's size, can effectively avoid going up centre gripping arm 43 and clamp arm 44 centre gripping in-process too extrudees tubular product, thereby cause tubular product or centre gripping driver 45's harm.

The transfer base 41 is provided with a first guide rail 5, the clamping base 42 is provided with a first slide block 51, and the transfer base 41 is provided with a moving component for driving the clamping base 42 to move along the length direction of the first guide rail 5.

The moving part can adopt a belt conveying, linear motor and screw rod transmission conveying structure.

As shown in fig. 5, the holder 42 is disposed in a right triangle configuration. A right-angle side is connected with the first guide rail 5, the other right-angle side is used as an installation side for installing the clamping seat 42, and a plurality of hollow grooves are formed in the clamping seat 42. The weight of the holder 42 is reduced, thereby securing the stability of the movement.

In addition, the clamping driver 45 includes a guide rail, a driving rack, a rotating gear engaged with the two driving racks, and a motor assembly or a cylinder assembly for driving the rotating gear to rotate.

When the motor assembly or the air cylinder assembly drives the rotating gear to rotate clockwise, the upper clamping arm 43 moves downwards, and the lower clamping arm 44 moves upwards to form clamping fit.

During counterclockwise rotation of the rotary gear, the upper clamp arm 43 moves upward and the lower clamp arm 44 moves downward to form a disengaging fit.

Above only the utility model discloses a preferred embodiment, the utility model discloses a scope not only limits in above-mentioned embodiment, and the fan belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (8)

1. A tubular product feeding system, characterized by: the automatic material distributing device comprises a material stack device (1), a conveying device (2), a material distributing device (3) and a transferring device (4), wherein the transferring device (4) and the material stack device (1) are respectively arranged on two sides of the conveying device (2), and the material stack device (1) comprises a coaming plate (11) and a plurality of bearing frames (12);

the conveying device (2) comprises a conveying frame (21), a plurality of groups of conveying chains (22), a feeding belt (23) and a feeding tray (24), one end of the feeding belt (23) is connected with the feeding tray (24) in a winding mode, the other end of the feeding belt is connected with the bearing frame (12), and when the feeding tray (24) drives the feeding belt (23) to be straightened, the pipes on the feeding belt (23) roll onto the conveying chains (22).

2. The pipe feeding system of claim 1, wherein: the bearing frame (12) is arranged in an L-shaped structure, one end of the feeding belt (23) is connected with the upper end of the bearing frame (12), the height position of the feeding disc (24) is lower than that of the upper end of the bearing frame (12), and the height position of the feeding disc (24) is higher than that of the conveying chain (22).

3. The pipe feeding system of claim 1, wherein: the conveying device (2) comprises a synchronous part (25) which drives a plurality of groups of conveying chains (22) to synchronously rotate, the synchronous part (25) comprises a synchronous motor (251), a synchronous shaft (252) and a plurality of groups of driving parts, and the driving parts comprise synchronous chains (253), driving wheels (254), driven wheels (255) and linkage shafts (256);

the synchronous motor (251) is used for driving a synchronous shaft (252) to rotate, and the synchronous shaft (252) is connected with a driving wheel (254);

the driving wheels (254) are connected through a synchronous chain (253);

the driven wheel (255) is connected with the conveying chain (22) through a linkage shaft (256).

4. A pipe feeding system as claimed in claim 1, wherein: the material distribution device (3) comprises a mounting seat (31), a driving piece (32) and a limiting plate (33);

the limiting plate (33) comprises a limiting portion (34) and a bearing portion (35) which are arranged on the top end, and a blocking portion (36), the limiting portion (34) and the blocking portion (36) are respectively arranged on two sides of the bearing portion (35), the height position of the limiting portion (34) is higher than that of the bearing portion (35), and a guide inclined plane (37) is arranged on the limiting portion (34).

5. The pipe feeding system of claim 4, wherein: the driving piece (32) comprises a driving motor and a driving gear, and a rack meshed with the driving gear is arranged on the limiting plate (33).

6. The pipe feeding system of claim 1, wherein: the transfer device (4) comprises a transfer seat (41) and a clamping seat (42) connected to the transfer seat (41) in a sliding mode, wherein an upper clamping arm (43), a lower clamping arm (44) and a clamping driver (45) are arranged on the clamping seat (42).

7. The pipe feeding system of claim 6, wherein: the clamping arms and the lower clamping arms (44) are detachably provided with anti-falling edges (46) at the ends far away from the clamping seat (42).

8. The pipe feeding system of claim 6, wherein: the transfer seat (41) is provided with a first guide rail (5), the clamping seat (42) is provided with a first sliding block (51), and the transfer seat (41) is provided with a moving part for driving the clamping seat (42) to move along the length direction of the first guide rail (5).

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