CN216827857U - Be applied to conveyer among chasing after shearing machine - Google Patents

Abstract

A conveying device applied to a chasing and shearing machine comprises a belt mounting seat, a fixed rack and a movable rack; the fixed frame is arranged at the top of the belt mounting seat; the left end of the fixed rack is provided with a driving guide roller mechanism, and the right end of the fixed rack is provided with a sliding groove; the left end of the movable rack is clamped in the sliding groove, and the movable rack can slide in the sliding groove along the left-right direction under the driving of the shearing knife; a first movable roller piece is arranged at the left end of the movable rack, and a second movable roller piece is arranged at the right end of the movable rack; the left end of the belt mounting seat is provided with a first guide roller assembly, and the right end of the belt mounting seat is provided with a first fixed roller assembly. The shearing knife drives the movable rack moves, the first movable roller, the second movable roller and the first fixed roller can keep the length of the belt, so that the tension of the belt is kept, and the conveying efficiency of the conveying device is guaranteed.

Description

Be applied to conveyer among chasing after shearing machine

Technical Field

The utility model relates to a chase after shearing machine technical field, especially, relate to a be applied to and chase after conveyer in shearing machine.

Background

The material cutting is an important component of the intelligent manufacturing industry, in the industry related to the production of material processing and forming, the completion of high-precision and high-quality cutting according to a set size is always an extremely important process, and the cutting effect of the material directly influences the production cost and the production quality. At present, the material cutting scheme mainly comprises: static cutting, dynamic cutting and chasing cutting. The material shearing and cutting method has the advantages that the material shearing and cutting method is developed rapidly due to the huge potential in the aspects of energy conservation and emission reduction and the great improvement of the processing and production efficiency of the material.

However, in the existing chasing and shearing equipment, the transportation device is connected with the shearing knife of the chasing and shearing device, so that the transportation device and the shearing knife can move in the process of chasing and shearing the steel strip, and a belt on the transportation device can be suspended, so that the transportation efficiency of the transportation device is influenced.

SUMMERY OF THE UTILITY MODEL

Problem to the background art provides, the utility model aims to provide a be applied to the conveyer among the chasing shears has solved the unsettled problem of conveyer belt.

To achieve the purpose, the utility model adopts the following technical proposal:

a conveying device applied to a chasing and shearing machine comprises a belt mounting seat, a fixed rack and a movable rack; the fixed frame is arranged at the top of the belt mounting seat; the left end of the fixed rack is provided with a driving guide roller mechanism, and the right end of the fixed rack is provided with a sliding groove; the left end of the movable rack is clamped in the sliding groove, and the movable rack can slide in the sliding groove along the left-right direction under the driving of the shearing knife; a first movable roller piece is arranged at the left end of the movable rack, and a second movable roller piece is arranged at the right end of the movable rack; the left end of the belt mounting seat is provided with a first guide roller assembly, and the right end of the belt mounting seat is provided with a first fixed roller assembly.

Preferably, the front end and the rear end of the first movable roller piece are provided with sliding wheels; the top of the belt mounting seat is provided with guide rail parts arranged on the left and the right; the sliding wheel is mounted on the guide rail part in a rolling manner.

Preferably, the driving guide roller mechanism comprises a driving motor, a transmission hinge and a driving roller assembly; the driving roller assembly is fixedly arranged at the leftmost end of the fixed frame; the driving roller assembly is provided with a plurality of driving rollers which are uniformly arranged along the left-right direction at intervals; and a driving shaft of the driving motor is in transmission connection with the driving roller through the transmission hinge, so that the driving roller can rotate around the axial direction of the driving roller.

Preferably, the live hinge comprises a first gear set and a second gear set; the outer part of the first gear set is meshed with the right end of the transmission hinge, and the first gear set is sleeved on a driving shaft of the driving motor; the outer part of the second gear set is meshed with the left end of the transmission hinge, and the second gear set is sleeved on the end part of the driving roller.

Preferably, the drive roller assembly further comprises a snap-in seat; one end of the clamping seat is fixedly connected with the left end of the fixed rack, and the other end of the clamping seat extends to the left outside of the fixed rack; the clamping seat is provided with a plurality of clamping grooves which are uniformly arranged along the left and right direction at intervals; the clamping groove comprises a connecting bearing seat; the end part of the driving roller is sleeved in the connecting bearing seat; the second gear assembly is provided with a connecting shaft, one end of the connecting shaft is sleeved inside the second gear assembly, and the other end of the connecting shaft is sleeved inside the connecting bearing seat.

Preferably, the first guide roller assembly comprises a second fixed roller and a conditioning roller assembly; the adjusting roller piece comprises an adjusting seat and an adjusting roller; the end part of the adjusting roller is clamped in the adjusting seat, and the adjusting seat can drive the adjusting roller to move in the vertical direction.

Preferably, the adjusting seat comprises an adjusting rod, a sliding bearing seat and a guide rail strip; the guide rail bar is vertically arranged inside the mounting seat; the sliding bearing seat is provided with an adjusting groove; the sliding bearing seat sleeve is clamped in the mounting seat through the mutual matching of the adjusting groove and the guide rail bar; the adjusting rod is arranged at the top of the mounting seat in a threaded connection mode, and the bottom of the adjusting rod penetrates through the mounting seat and is fixedly connected with the sliding bearing seat.

Compared with the prior art, one of the technical schemes has the following beneficial effects:

the shearing knife drives the movable rack moves, the first movable roller, the second movable roller and the first fixed roller can keep the length of the belt, so that the tension of the belt is kept, and the conveying efficiency of the conveying device is guaranteed.

Drawings

Fig. 1 is a schematic structural view of a transportation device according to an embodiment of the present invention;

fig. 2 is a schematic view of a mechanism for connecting a transportation device to a belt according to an embodiment of the present invention;

fig. 3 is a schematic view of a part of the structure of a transportation device according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a driving guide roller mechanism according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a first guide roller assembly according to an embodiment of the present invention.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicit to a number of technical features being indicated. Thus, features defined as "first", "second" and "third" may explicitly or implicitly include one or more of the features.

In a preferred embodiment of the present application, as shown in fig. 1 to 5, a transportation device applied to a chasing shear includes a belt mount 1, a fixed frame 2, and a moving frame 3; the fixed frame 2 is arranged at the top of the belt mounting seat 1; the left end of the fixed frame 2 is provided with a driving guide roller mechanism 21, and the right end of the fixed frame 2 is provided with a sliding groove 20; the left end of the movable rack 3 is clamped in the sliding groove 20, and the movable rack 3 can slide in the sliding groove 20 along the left-right direction under the driving of the shearing knife; a first movable roller piece 31 is arranged at the left end of the movable rack 3, and a second movable roller piece 32 is arranged at the right end of the movable rack 3; the left end of the belt mounting seat 1 is provided with a first guide roller assembly 11, and the right end of the belt mounting seat 1 is provided with a first fixed roller assembly 12.

The belt of the transport device described in this application is shown in fig. 2. In this embodiment, the movable frame 3 is connected to a cutting blade of the chasing and shearing machine, and when the chasing and shearing machine is chasing and shearing, the cutting blade drives the movable frame 3 to move in the sliding groove 20 along the left and right directions. Specifically, when the shearing knife drives the movable frame 3 to move leftward, the first movable roller 31 and the second movable roller 32 both move leftward, but the first fixed roller 12 is fixed. That is, the distance between the first movable roller 31 and the first fixed roller 12 is increased, but the distance between the second movable roller 32 and the first fixed roller 12 is decreased, so that the length of the belt between the first movable roller 31, the second movable roller 32 and the first fixed roller 12 is maintained. Similarly, when the shear knife drives the moving frame 3 to move to the right, the first moving roller 31 and the second moving roller 32 both move to the right, so that the length of the belt between the first moving roller 31, the second moving roller 32 and the first fixed roller 12 is also kept constant. Therefore, when the shearing knife drives the movable frame 3 to move, the length of the belt can be maintained through the first movable roller 31, the second movable roller 32 and the first fixed roller 12, so that the tension of the belt is maintained, and the conveying efficiency of the conveying device is ensured.

Preferably, the front and rear ends of the first movable roller 31 are provided with sliding wheels 311; the top of the belt mounting seat is provided with a guide rail part 13; the slide wheel 311 is fitted to the guide rail 13. As shown in fig. 3, when the chaser shears drives the moving frame 3, the moving frame 3 slides on the guide rail portion 13 via the sliding wheel 311, so that the moving frame 3 can move back and forth in the sliding groove 20. The arrangement can reduce the friction between the movable frame 3 and the fixed frame 2, reduce the loss between the two and prolong the service life. Preferably, the sliding wheels 311 slide on the guide rail parts 13, so that the moving frame 3 moves more smoothly in the sliding grooves 20, and the shearing knife can smoothly perform chasing shearing, thereby ensuring the production process of the steel strip.

Preferably, the driving guide roller mechanism 21 includes a driving motor 211, a transmission hinge 212, and a driving roller assembly 213; the driving roller assembly is fixedly arranged at the leftmost end of the fixed frame 2; the driving roller assembly 213 is provided with a plurality of driving rollers 2130, and the driving rollers 2130 are uniformly arranged along the left and right direction at intervals; the driving shaft of the driving motor 211 is in transmission connection with the driving roller 2130 through the transmission hinge 212, so that the driving roller 2130 can rotate around the axial direction of the driving roller 2130. As shown in fig. 4, the driving shaft of the driving motor 211 drives the transmission hinge 212 to rotate, and the rotation of the transmission hinge 212 drives the driving roller 2130 connected with the transmission hinge to rotate, so that the belt rotates on the transportation device, thereby implementing the transportation function. Specifically, the driving roller assembly 213 is provided with a plurality of driving rollers 2130, and the distance between each driving roller 2130 and the driving motor 211 is different. Such an arrangement may allow the transportation apparatus to use belts of different lengths, which are sleeved on the driving roller 2130 closer to the driving motor 211 when the belt is shorter, and the driving hinge 212 is connected to the same driving roller 2130. When the belt is long, the belt is sleeved on the driving roller 2130 with a longer distance from the driving motor 211, and the transmission hinge 212 is also connected with the driving roller 2130 with a longer distance, so that the application range of the transportation device is enlarged. More preferably, the belt is loosened after a period of use, and the length of the belt is increased, so that the driving roller 2130, which is farther from the driving motor 211, may be sleeved with the driving hinge 212 and the belt to maintain the tension of the belt.

Preferably, the live hinge 212 includes a first gear set 2121 and a second gear set 2122; the outer portion of the first gear set 2121 is engaged with the right end of the transmission hinge 212, and the first gear set 2121 is sleeved on the driving shaft of the driving motor 211; the outer portion of the second gear set 2122 is engaged with the left end of the transmission hinge 212, and the second gear set 2122 is sleeved on the end portion of the driving roller 2130. Specifically, as shown in fig. 4, the driving shaft of the driving motor 211 is connected to the right end of the driving hinge 212 through the first gear set 2121, and the left end of the driving hinge 212 is drivingly connected to the driving roller 2130 through the second gear set 2122, so that the driving motor 211 can drive the driving roller 2130 to rotate, thereby rotating the belt on the transportation device. The transmission arrangement is compact and simple in structure and stable in transmission, and the transmission hinge can be connected with the driving rollers 2130 with different distances by changing the length of the transmission hinge, so that the application range is enlarged.

Preferably, the drive roller assembly 213 further comprises a snap seat 2131; one end of the clamping seat 2131 is fixedly connected with the leftmost end of the fixed rack 2, and the other end of the clamping seat 2131 extends leftwards to the outside of the fixed rack 2; the clamping seat 2131 is provided with a plurality of clamping grooves 2132, and the clamping grooves 2132 are uniformly arranged along the left and right direction at intervals; the clamping groove 2132 comprises a connecting bearing seat 2133; the end part of the driving roller 2130 is sleeved in the connecting bearing seat 2133; the second gear set 2122 is provided with a connecting shaft 2134, one end of the connecting shaft 2134 is sleeved inside the second gear set 2122, and the other end of the connecting shaft 2134 is sleeved inside the connecting shaft bearing 2133. As shown in fig. 5, the driving roller 2130 is sleeved on the connecting bearing seat 2133, so as to be clamped in the clamping groove 2132. The plurality of engaging grooves 2132 are provided to mount a plurality of driving rollers 2130, thereby increasing the application range. Preferably, the second gear set 2122 is sleeved in the connecting shaft bearing 2133 through the connecting shaft 2134, so as to drive the driving roller 2130 to rotate, and the transmission structure is simple and compact, and the production and manufacturing cost is low.

Preferably, the first guide roller assembly 11 comprises a second fixed roller 111 and a regulating roller 112 assembly; the adjusting roller 112 comprises an adjusting seat 113 and an adjusting roller 112; the end of the adjusting roller 112 is clamped in the adjusting seat 113, and the adjusting seat 113 can drive the adjusting roller 112 to move in the vertical direction.

Preferably, the adjusting seat 113 includes an adjusting rod 1131, a sliding bearing seat 1132 and a guide rail 1133; the guide rail 1133 is vertically arranged inside the mounting seat; the sliding bearing block 1132 is provided with an adjusting groove; through the mutual matching of the adjusting groove and the guide rail 1133, the sliding bearing block 1132 is sleeved and clamped inside the mounting seat; adjust pole 1131 through threaded connection set up in the top of mount pad, just the bottom of adjusting pole 1131 passes the mount pad, with sliding bearing seat 1132 fixed connection.

As shown in fig. 2 and 3, in order to ensure the tightness of the belt, the first guide roller assembly 11 is provided in the present application. When the belt is too loose, the adjusting rod 1131 can be rotated to make the sliding bearing block 1132 move downwards in the adjusting block 113, so that the adjusting roller 112 also descends, thereby tensioning the belt and solving the problem of belt slack. When the belt is too tight, the adjusting rod 1131 can be rotated to enable the sliding bearing block 1132 to move upwards in the adjusting seat 113, so that the adjusting roller 112 also rises, thereby loosening the belt and solving the problem that the belt is too tight. Therefore, the first guide roller assembly 11 can conveniently and quickly adjust the tension degree of the belt, reduce the adjusting time and improve the adjusting efficiency.

The technical principle of the present invention is described above with reference to specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without any inventive effort, which would fall within the scope of the present invention.

Claims (7)

1. A conveying device applied to a chasing shear is characterized by comprising a belt mounting seat, a fixed rack and a movable rack;

the fixed frame is arranged at the top of the belt mounting seat;

the left end of the fixed rack is provided with a driving guide roller mechanism, and the right end of the fixed rack is provided with a sliding groove;

the left end of the movable rack is clamped in the sliding groove, and the movable rack can slide in the sliding groove along the left-right direction under the driving of the shearing knife;

a first movable roller piece is arranged at the left end of the movable rack, and a second movable roller piece is arranged at the right end of the movable rack;

the left end of the belt mounting seat is provided with a first guide roller assembly, and the right end of the belt mounting seat is provided with a first fixed roller assembly.

2. The transportation device applied to the chasing shears according to claim 1, wherein sliding wheels are arranged at the front end and the rear end of the first movable roller piece;

the top of the belt mounting seat is provided with guide rail parts arranged on the left and the right;

the sliding wheel is mounted on the guide rail part in a rolling manner.

3. The transportation device applied to the chasing shears according to claim 1, wherein the driving guide roller mechanism comprises a driving motor, a transmission hinge and a driving roller assembly;

the driving roller assembly is fixedly arranged at the leftmost end of the fixed frame;

the driving roller assembly is provided with a plurality of driving rollers which are uniformly arranged along the left-right direction at intervals;

and a driving shaft of the driving motor is in transmission connection with the driving roller through the transmission hinge, so that the driving roller can rotate around the axial direction of the driving roller.

4. A transportation device for use in a chasing shears according to claim 3, wherein the live hinge comprises a first gear set and a second gear set;

the outer part of the first gear set is meshed with the right end of the transmission hinge, and the first gear set is sleeved on a driving shaft of the driving motor;

the outer part of the second gear set is meshed with the left end of the transmission hinge, and the second gear set is sleeved on the end part of the driving roller.

5. A transporter for use in a chasing shears according to claim 4, wherein the drive roller assembly further comprises a snap-in seat;

one end of the clamping seat is fixedly connected with the left end of the fixed rack, and the other end of the clamping seat extends to the left outside of the fixed rack;

the clamping seat is provided with a plurality of clamping grooves which are uniformly arranged along the left and right direction at intervals;

the clamping groove comprises a connecting bearing seat;

the end part of the driving roller is sleeved in the connecting bearing seat;

the second gear assembly is provided with a connecting shaft, one end of the connecting shaft is sleeved inside the second gear assembly, and the other end of the connecting shaft is sleeved in the connecting bearing seat.

6. A transporting arrangement for use in a chasing shear as claimed in claim 1, wherein said first guide roller assembly includes a second fixed roller and a conditioning roller assembly;

the adjusting roller piece comprises an adjusting seat and an adjusting roller;

the end part of the adjusting roller is clamped in the adjusting seat, and the adjusting seat can drive the adjusting roller to move in the vertical direction.

7. The transportation device applied to the chasing shears according to claim 6, wherein the adjusting seat comprises an adjusting rod, a sliding bearing seat and a guide rail strip;

the guide rail bar is vertically arranged inside the mounting seat;

the sliding bearing seat is provided with an adjusting groove;

the sliding bearing seat sleeve is clamped in the mounting seat through the mutual matching of the adjusting groove and the guide rail bar;

the adjusting rod is arranged at the top of the mounting seat in a threaded connection mode, and the bottom of the adjusting rod penetrates through the mounting seat and is fixedly connected with the sliding bearing seat.

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