CN218579215U - Centering mechanism for steel belt conveying line - Google Patents

Abstract

The utility model discloses a centering mechanism for steel band transmission line, including frame, first mechanism, the second mechanism, linkage structure and actuating mechanism of rectifying, the frame is including setting up the backup pad on steel band production line and being located the frame top, first mechanism of rectifying includes first baffle, first baffle activity sets up in backup pad one end, the second mechanism of rectifying includes the second baffle, the second baffle activity sets up at the backup pad other end, set up relatively with first baffle, linkage structure sets up in the backup pad below, and linkage structure one end connects first baffle, the other end is connected with the second baffle, actuating mechanism sets up in the frame, a direction along perpendicular to steel band direction of delivery is removed in the backup pad for drive first baffle, first baffle passes through linkage structure and drives the second baffle and remove towards first baffle, in order to rectify the steel band in the backup pad to predetermineeing the position. The utility model discloses not only the regulation of rectifying is convenient, the security is high, and has improved the efficiency of rectifying.

Description

Centering mechanism for steel belt conveying line

Technical Field

The utility model relates to a steel band processing technology field specifically relates to a centering mechanism for steel band transmission line.

Background

On the steel strip processing line, in order to ensure uninterrupted processing of the steel strip, the tail end of the previous steel coil and the front end fed by the new steel coil are required to be cut by the shearing machine for the steel strip which is completely unreeled, so that the front end of the new fed steel coil is aligned to the tail end of the steel coil which is completely unreeled in a parallel and level mode, and then the steel strip is welded and butted by the welding machine, and continuous and uninterrupted feeding of the steel coil is realized. Before the welding, need align the tip of two steel bands, so need through set up the position of centering mechanism in order to adjust the steel band on the transfer line, the tip of steel band aligns around the realization, tradition is like 201157957Y discloses a welding conveying centering device, need set up the cylinder and adjust work platform's high back, promote the steel band to predetermineeing the height, then the anchor clamps that rethread hydro-cylinder promoted the steel band both sides remove, the stand direction centering of both sides is passed through again, overall structure is comparatively complicated, the action step is more, it is lower to lead to the centering efficiency of steel band.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides a adjust convenient, simple structure's centering mechanism for steel band transmission line.

The utility model discloses technical scheme as follows: the utility model provides a centering mechanism for steel band transmission line, includes frame, the first mechanism of rectifying, second mechanism, linkage structure and actuating mechanism of rectifying, the frame is including setting up the backup pad on the steel band production line and being located the frame top, the first mechanism of rectifying includes first baffle, and first baffle activity sets up in backup pad one end, and the second mechanism of rectifying includes the second baffle, and the second baffle activity sets up at the backup pad other end, sets up relatively with first baffle, and linkage structure sets up in the backup pad below, and linkage structure one end connects first baffle, and the other end is connected with the second baffle, and actuating mechanism sets up in the frame for drive first baffle removes along the direction of perpendicular to steel band direction of delivery in the backup pad, and first baffle passes through linkage structure and drives the second baffle and remove towards first baffle, so as to rectify the steel band in the backup pad to predetermineeing the position.

Furthermore, the two ends of the supporting plate are respectively provided with a long strip hole, the first baffle and the second baffle are respectively slidably mounted in the corresponding long strip holes, and the top ends of the first baffle and the second baffle respectively extend out of the upper portion of the supporting plate.

Furthermore, the rack comprises a plurality of guide rods which are arranged in parallel, and the guide rods are positioned below the supporting plate and are perpendicular to the conveying direction of the steel belt.

Furthermore, the first deviation correcting mechanism comprises a sliding plate, the sliding plate is slidably sleeved on the guide rods and is located at one end of the supporting plate, and the first baffle plate penetrates through the long hole of the supporting plate and is vertically and fixedly arranged on the sliding plate.

Furthermore, the second deviation rectifying mechanism comprises a sliding block, the sliding block is slidably sleeved on the guide rods and is located at the other end of the supporting plate, and the second baffle penetrates through the strip hole and is vertically and fixedly arranged on the sliding block.

Further, linkage structure includes gear, first rack and second rack, and the gear is installed in the backup pad bottom, all is provided with the tooth of cooperation gear on first rack and the second rack, and first rack one end rigid coupling is on the slide, and the other end passes through the tooth meshing on the gear, and second rack one end rigid coupling is on the slider, and the other end passes through the tooth meshing on the gear.

Furthermore, linkage structure includes first installation piece and second installation piece, and first installation piece sets firmly on one of them guide arm, and the relative slide one end activity of first rack sets up on first installation piece, and the second installation piece sets firmly in the backup pad bottom, and the relative slider one end activity of second rack sets up on the second installation piece.

Furthermore, the driving mechanism comprises a screw rod and a sliding rod, the screw rod is arranged below the supporting plate and parallel to the guide rod, the sliding rod is movably sleeved on the screw rod, the sliding plate is fixedly arranged on the sliding rod, the screw rod is rotated, the sliding rod axially moves along the screw rod, and accordingly the first baffle on the sliding plate is driven to move the deviation rectifying steel belt.

Furthermore, the centering mechanism comprises a scale plate, one end of the scale plate is slidably inserted into the rack, and the other end of the scale plate is fixedly connected to the sliding block and used for measuring the moving distance of the second baffle on the sliding block.

Furthermore, the centering mechanism comprises a lifting conveying mechanism arranged on the rack, the lifting conveying mechanism comprises a conveying roller, an elongated slot perpendicular to the conveying direction of the steel belt is formed in the supporting plate, the conveying roller is installed in the elongated slot of the supporting plate, and the top end of the conveying roller protrudes out of the top surface of the supporting plate.

Compared with the prior art: the utility model provides a centering mechanism for steel band transmission line, centering mechanism is provided with first baffle and second baffle respectively at backup pad both ends, be connected first baffle and second baffle through linkage structure, and drive first baffle through actuating mechanism and remove when rectifying a deviation and drive second baffle cooperation first baffle through linkage structure and rectify a deviation to preset position with the steel band of backup pad upper deviation, actuating mechanism accessible manual rotation screw rod or drive through drive arrangement such as motor and rotate, its simple structure, it is convenient to adjust, the security is high, efficiency of rectifying a deviation is improved; and the connection between the first baffle and the second baffle can be disconnected through the linkage structure according to the requirement, so that the single-side correction of the steel belt is realized.

Drawings

Fig. 1 is a side view of a centering mechanism for a steel strip conveying line according to the present invention.

Fig. 2 is a plan view of a centering mechanism for a steel strip conveying line according to the present invention.

Fig. 3 is a top view of the steel strip conveying line after the centering mechanism removes the supporting plate and the lifting and conveying mechanism.

In the figure:

1. a frame; 11. a support plate; 12. a guide bar; 2. a first deviation correcting mechanism; 21. a first baffle plate; 22. a slide plate; 3. a second deviation correcting mechanism; 31. a second baffle; 32. a slider; 4. a linkage structure; 41. a gear; 42. a first rack; 43. a second rack; 44. a fixed block; 45. a first mounting block; 46. a second mounting block; 5. a drive mechanism; 51. a screw; 52. a slide bar; 6. a scale plate; 7. a lifting and conveying mechanism; 71. a conveying roller; 72. a support arm; 73. a slide base; 74. a drive member; 8. and (4) pressing the rolls.

Detailed Description

The following detailed description of the embodiments of the present invention will be made with reference to the accompanying drawings. It is to be understood that the description of the embodiments herein is for purposes of illustration and explanation only and is not intended to limit the invention.

Referring to fig. 1-3, a centering mechanism for a steel strip conveying line includes a frame 1, a first deviation correcting mechanism 2, a second deviation correcting mechanism 3, a linkage mechanism 4 and a driving mechanism 5, where the frame 1 includes a supporting plate 11 disposed on a steel strip production line and located at the top end of the frame 1, a steel strip is conveyed along a steel strip conveying direction through the supporting plate 11, and the first deviation correcting mechanism 2 and the second deviation correcting mechanism 3 are respectively arranged at two ends of the supporting plate 11 for correcting the deviation of the steel strip. The linkage structure 4 is used for connecting the first deviation rectifying mechanism 2 and the second deviation rectifying mechanism 3, and the driving mechanism 5 is used for driving the first deviation rectifying mechanism 2 and the second deviation rectifying mechanism 3 to move and rectify deviation.

The first deviation rectifying mechanism 2 comprises a first baffle 21, the first baffle 21 is movably arranged at one end of the supporting plate 11, the second deviation rectifying mechanism 3 comprises a second baffle 31, and the second baffle 31 is movably arranged at the other end of the supporting plate 11 and is opposite to the first baffle 21. The linkage structure 4 is arranged below the supporting plate 11, and one end of the linkage structure 4 is connected with the first baffle plate 21, and the other end is connected with the second baffle plate 31. The driving mechanism 5 is arranged on the frame 1 and used for driving the first baffle plate 21 to move on the supporting plate 11 along the direction perpendicular to the conveying direction of the steel belt, and the first baffle plate 21 drives the second baffle plate 31 to move towards the first baffle plate 21 through the linkage structure 4 so as to correct the steel belt on the supporting plate 11 to a preset position.

The rack 1 comprises a plurality of guide rods 12 which are arranged in parallel, wherein the guide rods 12 are positioned below the supporting plate 11, are perpendicular to the conveying direction of the steel belt, and are used for respectively installing a first deviation rectifying mechanism 2, a second deviation rectifying mechanism 3 and a linkage structure 4.

Rectangular holes are respectively formed in two ends of the supporting plate 11, the first baffle plate 21 and the second baffle plate 31 are respectively slidably mounted in the corresponding rectangular holes, and the top ends of the first baffle plate 21 and the second baffle plate 31 extend out of the upper portion of the supporting plate 11 respectively. During deviation correction, the first baffle 21 and the second baffle 31 respectively move in opposite directions or in back directions along the length direction of the elongated hole.

The first deviation rectifying mechanism 2 comprises a sliding plate 22, the sliding plate 22 is slidably sleeved on the guide rods 12 and is located at one end of the supporting plate 11, and the first baffle 21 penetrates through a long hole of the supporting plate 11 and is vertically and fixedly arranged on the sliding plate 22. When the deviation is corrected, the driving mechanism 5 drives the sliding plate 22 to move to drive the first baffle 21 to move axially along the guide rod 12 for correcting the deviation.

The second deviation rectifying mechanism 3 comprises a sliding block 32, the sliding block 32 is slidably sleeved on the guide rods 12 and is located at the other end of the supporting plate 11, and the second baffle 31 penetrates through the long hole and is vertically and fixedly arranged on the sliding block 32. During deviation correction, the slide block 32 drives the second baffle 31 to move along the guide rod 12 towards the first baffle 21.

The linkage structure 4 comprises a gear 41, a first rack 42 and a second rack 43, the gear 41 is installed at the bottom of the support plate 11, teeth matched with the gear 41 are arranged on the first rack 42 and the second rack 43, one end of the first rack 42 is fixedly connected to the sliding plate 22, and the other end of the first rack is meshed with one end of the gear 41 through the teeth. One end of the second rack 43 is fixed on the slide block 32, and the other end is engaged with the other end of the gear 41 through teeth. During deviation correction, the driving mechanism 5 drives the sliding plate 22 to move to drive the first baffle 21 to move towards the sliding block 32, the sliding plate 22 drives the first rack 42 to move along the length direction of the guide rod 12, the rack correspondingly drives the gear 41 to rotate, the gear 41 correspondingly drives the second rack 43 to move along the length direction of the guide rod 12, and the moving directions of the first rack 42 and the second rack 43 are opposite, so that the second rack 43 drives the second baffle 31 on the sliding block 32 to move towards the first baffle 21, and the first baffle 21 is matched with the second baffle 31 to correct the deviation of the deviated steel belt.

Further, the linkage structure 4 includes a fixing block 44, and the fixing block 44 is fixedly disposed at the bottom of the supporting plate 11 for mounting the gear 41. The fixing block 44 is provided with a clamping groove, the gear 41 is rotatably installed in the clamping groove, and the teeth at the two ends of the gear 41 extend out of the clamping groove and are respectively engaged with the first rack 42 and the second rack 43.

The linkage structure 4 comprises a first mounting block 45, the first mounting block 45 is fixedly arranged on one of the guide rods 12, one end of the first rack 42, which is opposite to the sliding plate 22, is movably arranged on the first mounting block 45, and the first mounting block 45 is used for limiting the first rack 42 so as to prevent the first rack 42 from being disengaged from the gear 41 due to the deviation of the first rack 42 in the moving process, so that the first rack 42 cannot drive the second rack 43 to move through the gear 41.

The linkage structure 4 comprises a second mounting block 46, the second mounting block 46 is fixedly arranged at the bottom of the supporting plate 11, one end of the second rack 43, which is opposite to the sliding block 32, is movably arranged on the second mounting block 46, and the second mounting block 46 is used for limiting the second rack 43.

The driving mechanism 5 comprises a screw 51 and a sliding rod 52, the screw 51 is arranged on the frame 1, is positioned below the supporting plate 11 and is parallel to the guide rod 12, the sliding rod 52 is movably sleeved on the screw 51, and the sliding plate 22 is fixedly arranged on the sliding rod 52. The screw 51 is rotated, the sliding rod 52 moves along the axial direction of the screw 51, and accordingly the first baffle 21 on the sliding plate 22 is driven to move the deviation-rectifying steel belt, and the sliding plate 22 simultaneously drives the second baffle 31 on the sliding block 32 to cooperate with the first baffle 21 to move and rectify deviation through the linkage structure 4.

Further, the slide rod 52 is provided with a through hole along the axis thereof, and the inner wall of the through hole is provided with an internal thread matched with the screw 51.

It can be understood that the screw 51 can be rotated manually or driven by a driving device such as a motor according to requirements.

It can be understood that the second mounting block 46 can also be slidably disposed at the bottom of the supporting plate 11, the second rack 43 is slidably disposed on the sliding block 32 relative to one end of the second mounting block 46, the second mounting block 46 can be moved by the movement of the second mounting block 46, so that the second rack 43 is disengaged from the gear 41, the first rack 42 cannot drive the second rack 43 to move through the gear 41, the second baffle 31 cannot perform deviation rectification, and thus, the first baffle 21 can perform single-edge deviation rectification on the steel belt.

The centering mechanism comprises a scale plate 7, one end of the scale plate 7 is slidably inserted in the rack 1, and the other end of the scale plate is fixedly connected to the sliding block 32 and used for measuring the moving distance of the second baffle 31 on the sliding block 32, so that the positions of the second baffle 31 and the first baffle 21 deviation rectifying steel belt are controlled through the driving mechanism 5, and the deviation rectifying accuracy is improved.

The centering mechanism comprises a lifting conveying mechanism 8 arranged on the rack 1, the lifting conveying mechanism 8 comprises a conveying roller 71, a long groove perpendicular to the conveying direction of the steel belt is formed in the supporting plate 11, the conveying roller 71 is arranged in the long groove of the supporting plate 11, and the top end of the conveying roller protrudes out of the top surface of the supporting plate 11 and is used for conveying the steel belt.

The lifting conveying mechanism 8 comprises two supporting arms 72, a sliding seat 73 and a driving piece 74, the two supporting arms 72 are oppositely arranged on the machine frame 1, each supporting arm 72 is provided with a sliding groove in the vertical direction, and the sliding seat 73 is arranged in the sliding groove of each supporting arm 72 in a lifting manner and lifts along the sliding groove. The two ends of the conveying roller 71 are connected to the sliding seats 73 of the two supporting arms 72, the driving part 74 is arranged on each supporting arm 72, the telescopic rod of each driving part 74 penetrates through the top surface of the supporting arm 72 and extends into the sliding groove to be connected with the sliding seats 73, the sliding seats 73 are driven to lift along the height direction of the sliding groove, and the conveying rollers 71 on the two sliding seats 73 are correspondingly driven to lift so as to adjust the height or the tension of the steel belt. In this embodiment, the driving member 74 may be a pneumatic cylinder, a hydraulic cylinder or an electric motor.

In addition, centering mechanism still includes compression roller 8, and compression roller 8 is installed in backup pad 11 top surface one side for the steel band that pushes down through backup pad 11 top surface prevents that the steel band from perk in transportation.

To sum up, the utility model discloses be provided with first baffle 21 and second baffle 31 respectively at backup pad 11 both ends, be connected first baffle 21 and second baffle 31 through linkage structure 4, and drive first baffle 21 through actuating mechanism 5 and move and rectify the deviation and drive second baffle 31 through linkage structure 4 and cooperate first baffle 21 to rectify the steel band of off tracking on backup pad 11 to the preset position, actuating mechanism 5 can drive the rotation through drive arrangement such as manual rotation screw 51 or through motors, its simple structure, it is convenient to adjust, the security is high, the efficiency of rectifying a deviation has been improved; and the connection between the first baffle 21 and the second baffle 31 can be disconnected through the linkage structure 4 according to the requirement, so that the single-side correction of the steel belt is realized.

As long as the idea created by the present invention is not violated, various different embodiments of the present invention can be arbitrarily combined, and all the embodiments should be regarded as the content disclosed by the present invention; the utility model discloses an in the technical conception scope, carry out multiple simple variant and different embodiments to technical scheme and go on not violating the utility model discloses the arbitrary combination of the thought of creation all should be within the protection scope.

Claims (10)

1. The utility model provides a centering mechanism for steel band transmission line, includes frame (1), first mechanism (2), the second mechanism (3), linkage structure (4) and actuating mechanism (5) of rectifying, frame (1) is including setting up backup pad (11) on steel band production line and being located frame (1) top, its characterized in that: first mechanism (2) of rectifying includes first baffle (21), first baffle (21) activity sets up in backup pad (11) one end, second mechanism (3) of rectifying includes second baffle (31), second baffle (31) activity sets up at backup pad (11) the other end, set up with first baffle (21) relatively, linkage structure (4) set up in backup pad (11) below, and linkage structure (4) one end is connected first baffle (21), the other end is connected with second baffle (31), actuating mechanism (5) set up in frame (1), a direction removal along perpendicular to steel band direction of delivery is used for driving first baffle (21) in backup pad (11), first baffle (21) drive second baffle (31) through linkage structure (4) and move towards first baffle (21), in order to rectify the steel band in backup pad (11) to predetermineeing the position.

2. The centering mechanism as claimed in claim 1, wherein: rectangular hole has been seted up respectively to backup pad (11) both ends, and first baffle (21) and second baffle (31) slidable mounting are in corresponding rectangular hole respectively, and stretch out respectively to backup pad (11) top on the top of first baffle (21) and second baffle (31).

3. The centering mechanism as recited in claim 2, wherein: the machine frame (1) comprises a plurality of guide rods (12) which are arranged in parallel, and the guide rods (12) are positioned below the supporting plate (11) and are perpendicular to the conveying direction of the steel strip.

4. The centering mechanism as claimed in claim 3, wherein: the first deviation rectifying mechanism (2) comprises a sliding plate (22), the sliding plate (22) is slidably sleeved on the guide rods (12) and is located at one end of the supporting plate (11), and the first baffle (21) penetrates through a long hole of the supporting plate (11) and is vertically and fixedly arranged on the sliding plate (22).

5. The centering mechanism as claimed in claim 4, wherein: the second deviation rectifying mechanism (3) comprises a sliding block (32), the sliding block (32) is slidably sleeved on the guide rods (12) and is located at the other end of the supporting plate (11), and the second baffle (31) penetrates through the long-strip hole and is vertically and fixedly arranged on the sliding block (32).

6. The centering mechanism as claimed in claim 5, wherein: linkage structure (4) are including gear (41), first rack (42) and second rack (43), install in backup pad (11) bottom gear (41), all be provided with the tooth of cooperation gear (41) on first rack (42) and second rack (43), first rack (42) one end rigid coupling is on slide (22), the other end passes through the tooth meshing on gear (41), second rack (43) one end rigid coupling is on slider (32), the other end passes through the tooth meshing on gear (41).

7. The centering mechanism as claimed in claim 6, wherein: linkage structure (4) include first installation piece (45) and second installation piece (46), and first installation piece (45) set firmly on one of them guide arm (12), and first rack (42) relative slide (22) one end activity sets up on first installation piece (45), and second installation piece (46) set firmly in backup pad (11) bottom, and relative slider (32) one end activity of second rack (43) sets up on second installation piece (46).

8. The centering mechanism as claimed in claim 7, wherein: the driving mechanism (5) comprises a screw rod (51) and a sliding rod (52), the screw rod (51) is arranged below the supporting plate (11) and is parallel to the guide rod (12), the sliding rod (52) is movably sleeved on the screw rod (51), the sliding plate (22) is fixedly arranged on the sliding rod (52), the screw rod (51) is rotated, the sliding rod (52) axially moves along the screw rod (51), and accordingly the first baffle (21) on the sliding plate (22) is driven to move the deviation rectifying steel belt.

9. The centering mechanism as claimed in claim 7, wherein: the device comprises a scale plate (6), wherein one end of the scale plate (6) is slidably inserted into the rack (1), and the other end of the scale plate is fixedly connected to a sliding block (32) and used for measuring the moving distance of a second baffle (31) on the sliding block (32).

10. The centering mechanism as claimed in claim 1, wherein: the steel strip conveying device comprises a lifting conveying mechanism (7) arranged on a rack (1), wherein the lifting conveying mechanism (7) comprises a conveying roller (71), a long groove perpendicular to the conveying direction of a steel strip is formed in a supporting plate (11), the conveying roller (71) is arranged in the long groove of the supporting plate (11), and the top end of the conveying roller protrudes out of the top surface of the supporting plate (11).

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