CN217171063U - Alignment mechanism for corrugated board binding machine - Google Patents

Abstract

The application discloses an alignment mechanism for corrugated container board strapper belongs to corrugated container board strapper's technical field, and it includes the frame and installs the conveyer belt in the frame, and the top of conveyer belt is followed self width direction and is slided and install two synchronous boards, is provided with the drive assembly who is used for driving two synchronous boards and removes in opposite directions in the frame. The corrugated board after the bundling is kept orderly, so that the bundled corrugated board can be conveniently carried and stored.

Description

Alignment mechanism for corrugated board binding machine

Technical Field

The application relates to the technical field of corrugated board strapping machines, in particular to an aligning mechanism for a corrugated board strapping machine.

Background

The binding machine is used for reinforcing packaged articles, so that the articles are not scattered due to loose binding in the process of carrying and storing. The strapping machine straps the product or package with a strapping tape, then tightens the strapping tape and bonds its two ends by means of heat-melting and bonding with a heat-generating ironing head.

The binding machine utilizes the conveyer belt to transport a plurality of corrugated container boards that stack together, is provided with baffle and tying up the mechanism on the binding machine, and when corrugated container board transported to and was inconsistent with the baffle, corrugated container board stopped moving, and reuse tying up the mechanism and tie up corrugated container board.

With respect to the above-described related art, the inventors consider that: a plurality of corrugated container boards stack together through stacking mechanism, transport to the conveyer belt of strapper again, but because corrugated container board's quality is lighter, corrugated container board skew takes place easily in the transportation, leads to the corrugated container board untidy after tying up, is not convenient for carry and store the corrugated container board after tying up.

SUMMERY OF THE UTILITY MODEL

In order to improve the problem of untidy corrugated cardboard after binding, the application provides an alignment mechanism for a corrugated cardboard binding machine.

The application provides an alignment mechanism for corrugated container board strapper adopts following technical scheme:

the utility model provides an align mechanism for corrugated container board strapper, includes the frame and install in conveyer belt in the frame, the top of conveyer belt is followed self width direction and is slided and install two synchronous boards, be provided with in the frame and be used for driving two synchronous board drive assembly who removes in opposite directions.

By adopting the technical scheme, when the corrugated paper boards are bundled by the bundling mechanism, the two synchronous plates move towards the direction close to the corrugated paper boards, so that the corrugated paper boards are stacked neatly, the bundled corrugated paper boards are kept neat, and the bundled corrugated paper boards are convenient to carry and store.

Preferably, the driving assembly comprises a moving plate mounted on the frame and a connecting plate fixed on the top surface of the moving plate, a moving through groove is formed in the top surface of the moving plate, a moving block is fixed on the top surface of the synchronizing plate, the moving block is connected with the moving plate in a sliding manner along the width direction of the conveyor belt through the moving through groove, a fixed rod is fixed on the side surface of the moving block close to the connecting plate, a driving plate is fixed at one end of the fixed rod far away from the moving block, a driving through groove is formed in the top surface of the driving plate, a driving block is mounted on the driving plate in a sliding manner along the length direction of the conveyor belt through the driving through groove, a connecting rod is fixed on the side surface of the connecting plate close to the moving block, a vertically arranged rotating shaft is rotatably mounted at one end of the connecting rod far away from the connecting plate, and a driving shaft is fixed at the bottom end of the rotating shaft, one end of the driving shaft, which is far away from the rotating shaft, is rotationally connected with the driving block, and a rotating assembly used for driving the rotating shaft to rotate is arranged on the connecting plate.

Through adopting above-mentioned technical scheme, the axis of rotation rotates, drives the drive shaft and rotates, and the drive shaft drives the drive block and removes, and the drive block drives the drive plate and removes, because the drive plate passes through dead lever and movable block fixed connection, the movable block passes through the width direction removal that the groove was followed the conveyer belt through removing for the drive plate removes along the width direction of conveyer belt.

Preferably, a sliding groove is fixed on the top surface of the moving plate, a sliding block is fixed on the bottom surface of the driving plate, and the sliding block is connected with the moving plate in a sliding mode along the width direction of the conveying belt through the sliding groove.

Through adopting above-mentioned technical scheme, the drive plate passes through the slider and removes along the direction of transfer of conveyer belt for the difficult skew that takes place of the moving direction of drive plate.

Preferably, the rotating assembly comprises a motor and a first bevel gear fixed at the top end of the driving shaft, the two mutually adjacent side faces of the connecting plates are rotatably provided with a synchronizing rod, the outer peripheral face of the synchronizing rod is sleeved with a second bevel gear which is fixedly engaged with the first bevel gear, the output shaft of the motor is fixedly connected with one end of one of the synchronizing rods, one end of the two mutually adjacent synchronizing rods is provided with a synchronizing sleeve, the outer peripheral face of the synchronizing rod is provided with a limiting groove arranged along the length direction of the synchronizing sleeve, and the inner peripheral face of the synchronizing sleeve is fixedly provided with a limiting block inserted in the limiting groove.

By adopting the technical scheme, the two synchronizing rods synchronously rotate under the action of the synchronizing sleeve, the motor is started, the two synchronizing rods drive the two bevel gear II to synchronously rotate, and the bevel gear II drives the bevel gear I to rotate, so that the two synchronizing plates can simultaneously move.

Preferably, two the side that the connecting plate is close to each other all is fixed with the threaded rod, two the threaded rod one end that is close to each other is provided with adjusting sleeve, the threaded rod with adjusting sleeve screw drive cooperation.

Through adopting above-mentioned technical scheme, rotate adjusting sleeve, two threaded rods remove simultaneously for the interval between two movable plates changes, thereby changes the minimum interval between two synchronous boards, so that adapt to the corrugated container board of different width sizes.

Preferably, a bearing plate is fixed on the rack, a dovetail groove is formed in the top surface of the bearing plate, a dovetail block is fixed on the bottom surface of the moving plate, and the dovetail block is connected with the bearing plate in a sliding mode along the width direction of the conveyor belt through the dovetail groove.

Through adopting above-mentioned technical scheme, the movable plate slides along the width direction of conveyer belt through the dovetail piece to change the interval between two movable plates, and the movable plate is difficult for separating with the loading board.

Preferably, adjusting gear one is established to adjusting sleeve's outer peripheral face cover, the top of loading board is fixed with the roof, the top surface of roof rotates installs the control lever, the outer peripheral face cover of control lever establish be fixed with adjusting gear one intermeshing's adjusting gear two, the control lever is kept away from the one end of adjusting gear two is fixed with the control block, the through-hole has been seted up to the top surface of control block, wear to be equipped with the dwang in the through-hole.

Through adopting above-mentioned technical scheme, rotate the dwang, the dwang passes through the control block and drives the control lever rotation, and adjusting gear two drives adjusting gear one and rotates to it rotates to control adjusting sleeve.

Preferably, the top surface of the top plate is provided with an installation groove, and the bottom end of the rotating rod can be inserted into the installation groove.

Through adopting above-mentioned technical scheme, insert the bottom of dwang and establish in the mounting groove to make the dwang difficult emergence when nobody controls rotate, thereby lock the adjusting sleeve.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when the binding mechanism binds the corrugated boards, the two synchronous plates move towards the direction close to the corrugated boards, so that the plurality of corrugated boards are stacked orderly, and the bound corrugated boards are kept orderly, so that the bound corrugated boards can be conveniently carried and stored;

2. the rotating shaft rotates to drive the driving shaft to rotate, the driving shaft drives the driving block to move, the driving block drives the driving plate to move, and the driving plate is fixedly connected with the moving block through the fixed rod;

3. the two synchronous rods synchronously rotate under the action of the synchronous sleeve, the motor is started, the two synchronous rods drive the two bevel gear II to synchronously rotate, and the bevel gear II drives the bevel gear I to rotate, so that the two synchronous plates move simultaneously.

Drawings

Fig. 1 is a schematic overall structure diagram of an embodiment of the present application.

Fig. 2 is a sectional view taken along line a-a of fig. 1.

Fig. 3 is a schematic structural view of a synchronizing sleeve and an adjusting sleeve in the embodiment of the present application.

Fig. 4 is an enlarged schematic view at B in fig. 1.

Reference numerals: 1. a frame; 11. a conveyor belt; 12. a synchronization board; 2. a drive assembly; 21. a bearing frame; 211. a top plate; 212. a vertical plate; 213. a carrier plate; 214. a support plate; 22. moving the plate; 23. moving the through groove; 24. a moving block; 25. fixing the rod; 26. a drive plate; 27. driving the through groove; 28. a chute; 3. a connecting plate; 31. a connecting rod; 32. a rotating shaft; 33. a drive shaft; 34. a drive block; 35. a first bevel gear; 36. a dovetail groove; 37. a dovetail block; 4. a synchronization lever; 41. a limiting groove; 42. a synchronizing sleeve; 43. a limiting block; 44. a second bevel gear; 45. a motor; 5. a threaded rod; 51. an adjustment sleeve; 52. adjusting a first gear; 53. a second adjusting gear; 54. a control lever; 55. a control disc; 56. a control block; 57. a through hole; 58. rotating the rod; 59. and (4) mounting the groove.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses an alignment mechanism for a corrugated board strapping machine. Referring to fig. 1, an aligning apparatus for a corrugated cardboard binding machine includes a frame 1, and a conveyor belt 11 is provided on the frame 1. Two synchronous plates 12 are slidably mounted above the conveyor belt 11 along the width direction of the conveyor belt, and a driving assembly 2 for driving the two synchronous plates 12 to move oppositely is arranged on the frame 1.

Referring to fig. 1 and 2, the driving assembly 2 includes a bearing frame 21 fixed on the frame 1, the bearing frame 21 includes a top plate 211 horizontally disposed, vertical plates 212 are integrally formed on two opposite sides of the top plate 211, a bearing plate 213 is integrally formed on the side surfaces of the bottoms of the two vertical plates 212 close to each other, a supporting plate 214 is fixed on the bottom surface of the bearing plate 213, and the bottom end of the supporting plate 214 is fixedly connected with the frame 1. The top surface of the bearing plate 213 is provided with a moving plate 22, the top surface of the moving plate 22 is provided with a moving through groove 23, the top surface of the synchronous plate 12 is fixed with a moving block 24, and the moving block 24 is connected with the moving plate 22 in a sliding manner along the width direction of the conveyor belt 11 through the moving through groove 23.

Referring to fig. 2, a connecting plate 3 is integrally formed on the top surface of the moving plate 22, a connecting rod 31 is fixed on the side surface of the connecting plate 3 close to the moving block 24, and a rotating shaft 32 which is vertically arranged is rotatably installed on one side of the connecting rod 31 far away from the connecting plate 3. A first bevel gear 35 is fixedly sleeved on the outer peripheral surface of the top end of the rotating shaft 32, a driving shaft 33 is fixedly arranged at the bottom end of the rotating shaft 32, and a driving block 34 is rotatably arranged at one end, far away from the rotating shaft 32, of the driving shaft 33. Fixing rods 25 are fixed to the side face, close to the connecting plate 3, of the moving block 24, a driving plate 26 is fixed to one end, far away from the moving block 24, of each fixing rod 25, a driving through groove 27 is formed in the top face of each driving plate 26, and the driving block 34 is connected with the driving plate 26 in a sliding mode in the length direction of the conveyor belt 11 through the driving through groove 27. Two sliding grooves 28 are formed in the top surface of the moving plate 22, two sliding blocks are fixed to the bottom surface of the driving plate 26, and the sliding blocks are connected with the moving plate 22 in a sliding mode along the width direction of the conveyor belt 11 through the sliding grooves 28. The first bevel gear 35 is rotated, the first bevel gear 35 drives the rotating shaft 32 to rotate, and the rotating shaft 32 drives the driving block 34 to slide in the driving through groove 27 through the driving shaft 33, so as to drive the driving plate 26 to slide along the width direction of the conveyor belt 11.

Referring to fig. 1 and 3, the side surfaces of the two connecting plates 3 close to each other are rotatably provided with the synchronizing rods 4, one ends of the two synchronizing rods 4 close to each other are provided with synchronizing sleeves 42, and one ends of the synchronizing rods 4 far away from the connecting plates 3 penetrate through the synchronizing sleeves 42. The outer peripheral surface of the synchronizing rod 4 is provided with a limiting groove 41, the limiting groove 41 is arranged along the length direction of the synchronizing rod 4, and the inner peripheral surface of the synchronizing sleeve 42 is integrally formed with a limiting block 43 inserted in the limiting groove 41, so that the two synchronizing rods 4 can synchronously rotate. A motor 45 is fixed on the side surface of one of the connecting plates 3, and the output shaft of the motor 45 is fixedly connected with one end of the synchronizing rod 4 far away from the synchronizing sleeve 42. The outer peripheral surface of the synchronous rod 4 is fixedly provided with a second bevel gear 44 and a driving motor 45, the second bevel gear 44 is meshed with the first bevel gear 35, the two synchronous rods 4 rotate simultaneously, the synchronous rod 4 drives the second bevel gear 44 to rotate, the second bevel gear 44 drives the first bevel gear 35 to rotate, and the first bevel gear 35 drives the synchronous plate 12 to move.

Referring to fig. 2 and 3, a dovetail groove 36 is formed on the top surface of the carrier plate 213, a dovetail block 37 is fixed to the bottom surface of the moving plate 22, and the dovetail block 37 is slidably connected to the carrier plate 213 through the dovetail groove 36 in the width direction of the conveyor belt 11. Threaded rods 5 are fixed on the side faces, close to each other, of the two connecting plates 3, an adjusting sleeve 51 is arranged at one end, close to each other, of each threaded rod 5, and the threaded rods 5 are in screw transmission fit with the adjusting sleeve 51. The inner circumferential surface of the adjustment sleeve 51 is provided with female threads, and the female threads at both ends of the adjustment sleeve 51 are opposite in rotation direction.

Referring to fig. 3 and 4, a first adjusting gear 52 is fixedly sleeved on the outer circumferential surface of the adjusting sleeve 51, a control rod 54 is rotatably mounted on the top surface of the top plate 211, a second adjusting gear 53 is fixedly sleeved on the outer circumferential surface of the control rod 54, and the first adjusting gear 52 and the second adjusting gear 53 are meshed with each other. One end of the control rod 54 far away from the second adjusting gear 53 is fixed with a control disc 55, the side of the control disc 55 far away from the control rod 54 is fixed with a control block 56, a through hole 57 is formed in the top surface of the control block 56, a rotating rod 58 is arranged in the through hole 57 in a penetrating mode, a mounting groove 59 is formed in the top surface of the top plate 211, and the bottom end of the rotating rod 58 can be inserted in the mounting groove 59, so that the control disc 55 is not prone to rotate.

The implementation principle of the aligning mechanism for the corrugated board strapping machine in the embodiment of the application is as follows: the motor 45 is started, the two synchronizing rods 4 rotate synchronously, the first bevel gear 35 is driven to rotate through the second bevel gear 44, the rotating shaft 32 drives the driving shaft 33 to rotate, the driving shaft 33 drives the driving block 34 to move, the driving block 34 drives the driving plate 26 to move along the width direction of the conveying belt 11, so that the two synchronizing plates 12 move oppositely along the width direction of the conveying belt 11, the synchronizing plates 12 abut against the two opposite sides of the corrugated boards, and the corrugated boards are stacked orderly.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (7)

1. An alignment mechanism for a corrugated cardboard strapping machine, comprising a frame (1) and a conveyor belt (11) mounted on the frame (1), characterized in that:

two synchronous plates (12) are slidably mounted above the conveyor belt (11) along the width direction of the conveyor belt, and a driving assembly (2) for driving the two synchronous plates (12) to move oppositely is arranged on the rack (1);

the driving assembly (2) comprises a moving plate (22) installed on a rack (1) and a connecting plate (3) fixed to the top surface of the moving plate (22), a moving through groove (23) is formed in the top surface of the moving plate (22), a moving block (24) is fixed to the top surface of the synchronizing plate (12), the moving block (24) is connected with the moving plate (22) in a sliding mode along the width direction of the conveyor belt (11) through the moving through groove (23), a fixing rod (25) is fixed to the side face, close to the connecting plate (3), of the moving block (24), a driving plate (26) is fixed to one end, far away from the moving block (24), of the fixing rod (25), a driving through groove (27) is formed in the top surface of the driving plate (26), and a driving block (34) is installed on the driving plate (26) in a sliding mode along the length direction of the conveyor belt (11) through the driving through groove (27), a connecting rod (31) is fixed on the side face, close to the moving block (24), of the connecting plate (3), a vertically arranged rotating shaft (32) is rotatably mounted at one end, far away from the connecting plate (3), of the connecting rod (31), a driving shaft (33) is fixed at the bottom end of the rotating shaft (32), one end, far away from the rotating shaft (32), of the driving shaft (33) is rotatably connected with the driving block (34), and a rotating assembly used for driving the rotating shaft (32) to rotate is arranged on the connecting plate (3).

2. The alignment mechanism for a corrugated cardboard strapping machine as claimed in claim 1, characterized in that: a sliding groove (28) is fixed on the top surface of the moving plate (22), a sliding block is fixed on the bottom surface of the driving plate (26), and the sliding block is connected with the moving plate (22) in a sliding mode along the width direction of the conveyor belt (11) through the sliding groove (28).

3. The alignment mechanism for a corrugated cardboard strapping machine as claimed in claim 1, characterized in that: the rotating assembly comprises a motor (45) and a first bevel gear (35) fixed at the top end of the driving shaft (33), the two connecting plates (3) are rotatably provided with synchronizing rods (4) on the side surfaces close to each other, a second bevel gear (44) meshed with the first bevel gear (35) is fixedly sleeved on the outer peripheral surface of each synchronizing rod (4), the output shaft of the motor (45) is fixedly connected with one end of one synchronizing rod (4), a synchronizing sleeve (42) is arranged at one end, close to each other, of each synchronizing rod (4), a limiting groove (41) arranged in the length direction of the outer peripheral surface of each synchronizing rod (4) is formed, and a limiting block (43) inserted into the limiting groove (41) is fixedly arranged on the inner peripheral surface of each synchronizing sleeve (42).

4. The alignment mechanism for a corrugated cardboard strapping machine as claimed in claim 1, characterized in that: two threaded rods (5) are fixed on the side faces, close to each other, of the connecting plates (3), one ends, close to each other, of the threaded rods (5) are provided with adjusting sleeves (51), and the threaded rods (5) are in screw transmission fit with the adjusting sleeves (51).

5. The alignment mechanism for a corrugated cardboard strapping machine as claimed in claim 4, characterized in that: the bearing plate (213) is fixed on the rack (1), a dovetail groove (36) is formed in the top surface of the bearing plate (213), a dovetail block (37) is fixed on the bottom surface of the moving plate (22), and the dovetail block (37) is connected with the bearing plate (213) in a sliding mode along the width direction of the conveyor belt (11) through the dovetail groove (36).

6. The alignment mechanism for a corrugated cardboard strapping machine as claimed in claim 5, characterized in that: adjusting gear (52) are fixed with to the outer peripheral face cover of adjusting sleeve (51), the top of loading board (213) is fixed with roof (211), the top surface of roof (211) is rotated and is installed control lever (54), the outer peripheral face cover of control lever (54) establish be fixed with adjusting gear (52) intermeshing's adjusting gear two (53), control lever (54) are kept away from the one end of adjusting gear two (53) is fixed with control block (56), through-hole (57) have been seted up to the top surface of control block (56), wear to be equipped with dwang (58) in through-hole (57).

7. The alignment mechanism for a corrugated cardboard strapping machine as claimed in claim 6, characterized in that: mounting groove (59) have been seted up to the top surface of roof (211), the bottom of dwang (58) can be inserted and is established in mounting groove (59).

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