CN112845915A - Shaping location integral type aluminum sheet conveyor and aluminum sheet system of processing - Google Patents

Abstract

The invention relates to the technical field of aluminum sheet processing, and discloses a forming and positioning integrated aluminum sheet conveying device and an aluminum sheet processing system, wherein the forming and positioning integrated aluminum sheet conveying device comprises a conveyor body, and the conveyor body is provided with: the aluminum sheet shaping and conveying device comprises a first shaping positioning barrel and a second shaping positioning barrel which are arranged oppositely, wherein a shaping conveying space of an aluminum sheet is formed between the first shaping positioning barrel and the second shaping positioning barrel; the stepping motor synchronously drives the first shaping positioning barrel and the second shaping positioning barrel through a transmission mechanism. The forming and positioning integrated aluminum sheet conveying device provided by the invention can ensure that the first shaping positioning cylinder does not apply excessive pressure to the aluminum sheet when the aluminum sheet is rolled, can adapt to vertical sliding on the adjusting plate, further does not damage the aluminum sheet due to excessive pressure, the first limiting plate plays a role in guiding the aluminum sheet, and the roller on the supporting plate enables the aluminum sheet to smoothly pass through when passing.

Description

Shaping location integral type aluminum sheet conveyor and aluminum sheet system of processing

Technical Field

The invention relates to the technical field of aluminum sheet processing, in particular to a forming and positioning integrated aluminum sheet conveying device and an aluminum sheet processing system.

Background

In the prior art, an aluminum sheet is a commonly used aluminum sheet using mode, and the aluminum sheet processing process comprises a step of enabling a long-strip-shaped aluminum sheet cutting mechanism to be equal in length and a small-size aluminum sheet, wherein in the step, the aluminum sheet needs to be conveyed intermittently and equally to enable a cutting mechanism knife to cut the small-size aluminum sheet with equal length.

Like publication number CN204685817U, the name is "an aluminum sheet automatic processing device", authorizes the utility model patent that the publication date is 20151007, and it includes aluminum sheet blowing machine, flattening feeder, punch press and waste recovery machine, aluminum sheet blowing machine, flattening feeder, punch press and waste recovery machine all link to each other with controlling means, the punch press includes the punch press body, be provided with mould and lower mould on the punch press body, be a through-hole in the cutting mechanism mouth of lower mould, the through-hole below is provided with the conveyer belt, the conveyer belt other end is provided with the storage frame, and this kind of aluminum sheet automatic processing device has saved manual operation, can be automatically with the aluminum sheet of whole book rush out the aluminum sheet of fixed shape, the waste material lapping that will rush out after the aluminum sheet is retrieved simultaneously.

The defects of the prior art including the patent are that the surface of the aluminum sheet is easy to deform in the conveying process before cutting due to the over-soft texture of the aluminum sheet and the complex processing environment of the aluminum sheet, and the positioning structure in the prior art is complex, the vibration is large, and the defects are caused in the accurate positioning and cutting of the aluminum sheet.

Disclosure of Invention

An aspect of the present invention is to provide a forming and positioning integrated aluminum sheet conveying device and an aluminum sheet processing system to solve the above-mentioned disadvantages of the prior art.

Technical scheme

In order to solve the technical problem, the embodiment of the invention adopts the following technical scheme:

the utility model provides a shaping location integral type aluminum sheet conveyor, includes the conveyer body, be provided with on the conveyer body: the aluminum sheet shaping and conveying device comprises a first shaping positioning barrel and a second shaping positioning barrel which are arranged oppositely, wherein a shaping conveying space of an aluminum sheet is formed between the first shaping positioning barrel and the second shaping positioning barrel; the stepping motor synchronously drives the first shaping positioning cylinder and the second shaping positioning cylinder through a transmission mechanism; the first rotating shaft at the end part of the first shaping positioning cylinder is connected to the adjusting plate in a sliding mode, the sliding direction of the first rotating shaft is perpendicular to the conveying direction of the aluminum sheet, the transmission mechanism comprises a belt pulley assembly, the first rotating shaft is driven by the belt pulley assembly, and a tensioning wheel is arranged on the belt pulley assembly; still include conflict mechanism, conflict mechanism both ends are connected respectively the regulating plate with first pivot, conflict pressure of conflict mechanism is configured to be greater than the deformation pressure of aluminum sheet.

Preferably, the aluminum sheet feeding device further comprises a pressing box and a locking mechanism, the adjusting plate is arranged in the pressing box in a sliding mode, the sliding direction of the adjusting plate is perpendicular to the conveying direction of the aluminum sheet, and the locking mechanism is used for locking the adjusting plate in the pressing box at any position.

Preferably, the first shaping positioning cylinder, the second shaping positioning cylinder and the belt pulley assembly are all located in the pressing box.

Preferably, the output end of the stepping motor is fixedly provided with a moving gear, the moving gear is meshed with an input gear of the transmission mechanism, and the transmission mechanism is a gear assembly.

Preferably, the abutting mechanism comprises an inclined block, a first spring and a moving block, the inclined block is arranged on the outer wall of the adjusting plate in a sliding mode through the moving block, the first spring is arranged between the inclined block and the outer wall of the adjusting plate, a stress block is arranged on the outer wall of the adjusting plate in a sliding mode, a pushing block is fixedly arranged at the top of the stress block, the pushing block is in wedge-shaped fit with the inclined block, and the inclined block abuts against the first rotating shaft in a sliding mode.

Preferably, the belt pulley assembly comprises a driving belt pulley, a first connecting belt and a driven belt pulley, the driving belt pulley is rotatably connected to the inner wall of the pressure box, the first connecting belt is sleeved on the driving belt pulley and the driven belt pulley, a first shaping positioning cylinder is fixedly installed on the driven belt pulley, and the end part of the first shaping positioning cylinder is rotatably connected to the stress block.

Preferably, a sliding block is slidably mounted on a guide plate arranged on the inner wall of the pressing box, the adjusting plate is fixedly mounted on the sliding block, a connecting plate is arranged on the adjusting plate, a displacement block is slidably arranged on the connecting plate, a second spring is arranged between the displacement block and the connecting plate, the tensioning wheel is rotatably connected to the displacement block, and the tensioning wheel vertically abuts against and tensions the first connecting belt through an acting force applied by the second spring.

Preferably, the inclined plane block is in sliding contact with the first shaping positioning barrel.

As preferred, it is provided with the backup pad to press the incasement wall, it is provided with the cylinder to be the coupling of linear distribution in the backup pad, the top fixed mounting of backup pad has the roof, slidable mounting has the second limiting plate on the roof, the top fixed mounting of roof has the slide, the second limiting plate through with the top set up second nut threaded connection with the slide is fixed, the slide with the discharge gate that the incasement wall was seted up is corresponding.

The embodiment of the invention also provides an aluminum sheet processing system which comprises a positioning device and a cutting mechanism which are sequentially arranged along the conveying direction, wherein the positioning device is the forming and positioning integrated aluminum sheet conveying device.

Compared with the prior art, the embodiment of the invention has the following beneficial effects:

1. according to the invention, before the aluminum sheet is conveyed to the cutting mechanism to be cut, the aluminum sheet passes through the first shaping positioning cylinder and the second shaping positioning cylinder on the conveyor body, and the second shaping positioning cylinder can deform the aluminum sheet due to the abutting force of the abutting mechanism, so that the bulge on the surface of the aluminum sheet can be rolled, further, the defective product with the bulge on the surface can be subjected to secondary forming, and the quality of a finished product is improved.

2. According to the invention, the driving gear assembly is driven by the stepping motor, and the rotating turns of the first shaping positioning cylinder and the first shaping positioning cylinder are controlled according to requirements through the second connecting belt and the belt pulley assembly, so that the positioning and the interval conveying of the aluminum sheet to the cutting mechanism are realized, the length of the aluminum sheet during cutting is controlled, and the aluminum sheet is cut into sheets.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

This document provides an overview of various implementations or examples of the technology described in this disclosure, and is not a comprehensive disclosure of the full scope or all features of the disclosed technology.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of a partial structure inside the press box according to the present invention;

FIG. 3 is a schematic view of another embodiment of the present invention;

FIG. 4 is a schematic view of the structure of the transmission mechanism of the present invention;

FIG. 5 is a schematic view of a second limiting plate structure in the pressing box according to the present invention;

FIG. 6 is a schematic view of a support plate according to the present invention;

FIG. 7 is an enlarged schematic view of the top plate of the present invention;

FIG. 8 is a schematic view of a guide plate structure according to the present invention;

FIG. 9 is a schematic view of a structure of a collision mechanism according to the present invention;

FIG. 10 is a schematic view of a structure of a baffle plate on a conveyor body according to the present invention;

FIG. 11 is a schematic view of the construction of the tensioning bearing mount of the present invention;

FIG. 12 is an enlarged view of the structure of the present invention at A;

FIG. 13 is an enlarged view of the structure of the present invention at B;

FIG. 14 is an exploded view of the driving mechanism and the abutting mechanism of the present invention;

FIG. 15 is a schematic view of the overall structure of the present invention;

FIG. 16 is a schematic view of a cutting mechanism and a guide base according to the present invention;

FIG. 17 is a partial structural view of a stent according to the present invention;

FIG. 18 is a schematic view of the bottom structure of the arc base of the present invention;

FIG. 19 is a schematic view of the construction of the cutting assistance plate and the bottom support plate of the present invention;

FIG. 20 is a schematic view of the first and second racks of the present invention;

FIG. 21 is an exploded view of the arc seat and bottom support plate of the present invention;

FIG. 22 is an exploded view of a cutting assistance plate according to the present invention;

FIG. 23 is a schematic view of a cutting mechanism according to the present invention.

In the figure: 1. a conveyor body; 2. a baffle plate; 3. pressing the box; 4. a support; 5. a stepping motor; 6. a drive pulley; 7. an adjusting plate; 8. a connecting plate; 9. a first shaping positioning cylinder; 10. a second shaping positioning cylinder; 11. a first pulley; 12. a support plate; 13. a processing table; 14. a support; 15. an arc-shaped seat; 101. tensioning the bearing block; 201. a transverse plate; 202. a first limit plate; 301. a guide plate; 302. a slider; 303. a discharge port; 501. a traveling gear; 502. a first linkage rod; 503. a first gear; 504. a second linkage rod; 505. a third link lever; 506. a second gear; 601. a first connecting belt; 701. a stress block; 702. a pushing block; 703. a bevel block; 704. a first spring; 705. a moving block; 801. a second spring; 802. a displacement block; 803. a tension wheel; 901. a driven pulley; 1001. a second pulley; 1101. a second connecting band; 1102. a third gear; 1201. a drum; 1202. a top plate; 1203. a slide plate; 1204. a second limiting plate; 1301. a fixed seat; 1302. a guide seat; 1303. a cutting mechanism; 1304. a first rack; 1401. a second rack; 1402. a first resisting block; 1403. a first straight gear; 1404. a second spur gear; 1405. a poke rod; 1406. a second resisting block; 1407. a third spring; 1408. a fourth spring; 1409. cutting the auxiliary plate; 1410. a bottom support plate; 1501. rotating the block; 1502. connecting blocks; 1503. a fifth spring; 1504. a stress plate; 1505. a slide bar; 1506. a U-shaped groove.

Detailed Description

So that the objects, technical solutions and advantages of the embodiments of the present disclosure will be more apparent, the technical solutions of the embodiments of the present disclosure will be clearly and completely described below with reference to the drawings of the embodiments of the present disclosure. It is to be understood that the described embodiments are only a few embodiments of the present disclosure, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the described embodiments of the disclosure without any inventive step, are within the scope of protection of the disclosure.

Unless otherwise defined, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this disclosure belongs. The use of the word "comprising" or "comprises", and the like, in this disclosure is intended to mean that the elements or items listed before that word, include the elements or items listed after that word, and their equivalents, without excluding other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may also include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

As shown in fig. 1 to 14, an aluminum sheet conveying device integrated with molding and positioning provided by an embodiment of the present invention includes a conveyor body 1, where the conveyor body 1 is provided with: a first shaping positioning cylinder 9 and a second shaping positioning cylinder 10 which are arranged oppositely, and a shaping conveying space of an aluminum sheet is formed between the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10; the stepping motor 5 synchronously drives the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 through a transmission mechanism; the adjusting plate 7 is connected with a first rotating shaft at the end part of the first shaping positioning cylinder 9 in a sliding mode, the sliding direction of the first rotating shaft is perpendicular to the conveying direction of the aluminum sheet, the transmission mechanism comprises a belt pulley assembly, the first rotating shaft is driven by the belt pulley assembly, and a tension pulley 803 is arranged on the belt pulley assembly; the aluminum sheet deformation device further comprises a collision mechanism, two ends of the collision mechanism are respectively connected with the adjusting plate 7 and the first rotating shaft, and the collision pressure of the collision mechanism is configured to be larger than the deformation pressure of the aluminum sheet.

Specifically, the conveyer body 1 is arranged at the last station of the cutting mechanism of the aluminum sheet processing system, the aluminum sheet output by the conveyer body is directly sent to the cutting mechanism to be cut in the same size, the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 are oppositely arranged, a gap between the first shaping positioning cylinder and the second shaping positioning cylinder forms a shaping conveying space of the aluminum sheet, the shaping conveying space is butted with a conveying device of the aluminum sheet, such as a conveying belt, the aluminum sheet conveyed by the conveying device directly enters the shaping conveying space, generally speaking, the size of the shaping conveying space is equal to or slightly smaller than the design thickness of the aluminum sheet, and the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 can have certain extrusion force on the passing aluminum sheet. The first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 receive synchronous control of the stepping motor 5 and the transmission mechanism, and the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 rotate synchronously and reversely, so that the first shaping positioning cylinder and the second shaping positioning cylinder can receive control of the same transmission mechanism, such as a gear assembly, a belt wheel assembly and a chain wheel assembly which are the same, only a steering wheel needs to be arranged between the transmission mechanisms, and the steering wheel is common knowledge in the field of machinery and is not repeated. For a specific transmission mechanism, the transmission ratio can be calculated and controlled, and because the stepping motor 5 is used as a driving device, the rotation amplitude of the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 can be accurately controlled by controlling the rotation amplitude of the stepping motor 5, so that the accurate control of the conveying size of the aluminum sheet is realized, the accurate positioning of the aluminum sheet is realized, and the downstream cutting mechanism can obtain the consistent small-size aluminum sheet.

This embodiment still includes conflict mechanism, conflict mechanism both ends are connected regulating plate 7 and first pivot respectively, conflict mechanism is used for applying the pressure of regulating plate 7 for first moulding location section of thick bamboo 9 through first pivot, optionally, conflict mechanism is a connecting rod or supporting structure, preferably, conflict mechanism is the elastic expansion mechanism that length can be controlled, can control the distance between first moulding location section of thick bamboo 9 and the moulding location section of thick bamboo 10 of second through conflict mechanism, in this embodiment, conflict mechanism goes out the size and is configured its conflict pressure to be greater than the deformation pressure of aluminum sheet, also be more than moulding transport space if the thickness of aluminum sheet, the extrusion force between first moulding location section of thick bamboo 9 and the moulding location section of thick bamboo 10 of second this moment is enough to make the aluminum sheet discover to warp, realize the remolding to the aluminum sheet promptly.

According to the forming and positioning integrated aluminum sheet conveying device and the aluminum sheet processing system, before an aluminum sheet is conveyed to a cutting mechanism to be cut, the aluminum sheet passes through the first forming and positioning cylinder 9 and the second forming and positioning cylinder 10 on the conveyor body 1, and the first forming and positioning cylinder 9 can deform the aluminum sheet due to the resisting pressure of the resisting mechanism, so that the protruding part on the surface of the aluminum sheet can be rolled, further secondary forming is performed on a defective product with the protruding part on the surface, and the quality of a finished product is improved. Simultaneously, make the drive gear subassembly through step motor 5 to through the number of revolutions of second connecting band 1101 and belt pulley subassembly according to first moulding location section of thick bamboo 9 of demand control and the moulding location section of thick bamboo 10 of second, realize fixing a position and clearance and carry the aluminum sheet to cutting mechanism, thereby the length of aluminum sheet when the control cutting is the slice with the aluminum sheet cutting, so, first moulding location section of thick bamboo 9 and the moulding location section of thick bamboo 10 of second have the accurate transport of location and fashioned effect simultaneously.

In another embodiment of the present invention, as shown in fig. 1 and fig. 2, the present invention further comprises a pressing box 3 and a locking mechanism, wherein the pressing box 3 is a housing structure, and is used for wrapping the transmission mechanism and the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 to form a semi-closed or closed structure, the adjusting plate 7 is slidably disposed in the pressing box 3, that is, the adjusting plate 7 itself can move in the pressing box 3, the sliding direction of the adjusting plate 7 is perpendicular to the conveying direction of the aluminum sheet, the locking mechanism is used for locking the adjusting plate 7 in the pressing box 3 at any position, the size between the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 can be adjusted by sliding the adjusting plate 7, and is further adapted to aluminum sheets with different thicknesses, the adjusting plate 7 is locked to corresponding target positions by the locking mechanism, and the locking mechanism can be a screw thread locking device, The clamping mechanism and other positioning or locking mechanisms known in the art are not described in detail.

Preferably, the locking mechanism includes a bolt, a through groove is formed on an outer wall of one side of the pressing box 3, the through groove is used for facilitating the handle of the adjusting plate 7 to penetrate to the outside (as shown in the state of fig. 7 and 8), and after the adjusting plate 7 is slidably adjusted on the guide plate 301 by applying pressure on the handle, the adjusting plate 7 is fixed by the bolt to be locked (as shown in the state of fig. 3 and 5).

Preferably, as shown in fig. 5 and 3, the first shaping positioning cylinder 9, the second shaping positioning cylinder 10 and the pulley assembly are located in the pressing box 3, so as to protect the first shaping positioning cylinder 9, the second shaping positioning cylinder 10 and the pulley assembly.

In another embodiment of the present invention, preferably, the output end of the stepping motor 5 is fixedly installed with a moving gear 501, the moving gear 501 is engaged with an input gear of a transmission mechanism, and the transmission mechanism is a gear assembly, and the use of the gear assembly has an advantage that the transmission ratio can be controlled more accurately, so that the aluminum sheet can be conveyed and positioned more accurately.

In another embodiment of the present invention, preferably, as shown in fig. 13 and 14, the abutting mechanism includes an inclined block 703, a first spring 704 and a moving block 705, the inclined block 703 is slidably disposed on an outer wall of the adjusting plate 7 through the moving block 705, the first spring 704 is disposed between the inclined block 703 and the outer wall of the adjusting plate 7, the outer wall of the adjusting plate 7 is slidably disposed with a force-receiving block 701, a pushing block 702 is fixedly mounted on a top of the force-receiving block 701, the pushing block 702 is in wedge-shaped fit with the inclined block 703, and the inclined block 703 is slidably abutted to the first rotating shaft. When the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 are matched to carry out secondary shaping on the aluminum sheet, when the pressure applied to the aluminum sheet is too large, the first shaping positioning cylinder 9 upwards slides on the adjusting plate 7 through the stress block 701, so that the push block 702 is abutted to the inclined plane block 703, the inclined plane block 703 moves back and forth on the adjusting plate 7 through the moving block 705 (as shown in a state of fig. 13), and further when the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 carry out secondary shaping on the aluminum sheet, the pressure of the first shaping positioning cylinder 9 is adapted to the automatic adjusting space, and the aluminum sheet is prevented from being damaged due to the fact that the pressure of the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 is too large.

In another embodiment of the present invention, as shown in fig. 13 and 14, the pulley assembly includes a driving pulley 6, a first connecting belt 601 and a driven pulley 901, the driving pulley 6 is rotatably connected to the inner wall of the pressure box 3, the first connecting belt 601 is sleeved on the driving pulley 6 and the driven pulley 901, the first shaping positioning cylinder 9 is fixedly installed on the driven pulley 901, an end of the first shaping positioning cylinder 9 is rotatably connected to the force-receiving block 701, and one end of the first shaping positioning cylinder 9 penetrates through the driven pulley 901 to the outside and is rotatably installed on the force-receiving block 701.

More preferably, the belt wheel of the belt wheel assembly uses a chain wheel, and the edge of the belt uses a chain, so as to prevent the phenomenon of inaccurate positioning size of the slipping belt wheel, and further improve the conveying accuracy of the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10.

In still another embodiment of the present invention, as shown in fig. 8, 13 and 14, a sliding block 302 is slidably mounted on a guiding plate 301 disposed on an inner wall of a pressing box 3, an adjusting plate 7 is fixedly mounted on the sliding block 302, a connecting plate 8 is disposed on the adjusting plate 7, a displacement block 802 is slidably disposed on the connecting plate 8, a second spring 801 is disposed between the displacement block 802 and the connecting plate 8, a tension wheel 803 is rotatably connected to the displacement block 802, the tension wheel 803 vertically abuts against and tensions the first connecting belt 601 through an acting force exerted by the second spring 801, when the first shaping positioning cylinder 9 automatically adapts to a pressure exerted on an aluminum sheet, when the driven pulley 901 on the first shaping positioning cylinder 9 slides upward, the displacement block 802 inside the connecting plate 8 can exert a tension on the first connecting belt 601 under a tension force of the second spring 801, and during the upward sliding of the driven pulley 901, and then make first connecting band 601 when first moulding location section of thick bamboo 9 upward displacement, can ensure that first connecting band 601 and drive pulley 6 and driven pulley 901 between can not become flexible, when having improved first moulding location section of thick bamboo 9 upward displacement, the stability of first connecting band 601 transmission drive pulley 6 and driven pulley 901.

In yet another embodiment of the present invention, as shown in fig. 13 and 14, the ramp block 703 is slidably abutted against the first shaping positioning cylinder 9. As shown in fig. 3, 5 and 6, a supporting plate 12 is disposed on an inner wall of the pressure box 3, rollers 1201 are disposed on the supporting plate 12 in a linear distribution coupling manner, a top plate 1202 is fixedly mounted on a top portion of the supporting plate 12, a second limiting plate 1204 is slidably mounted on the top plate 1202, a sliding plate 1203 is fixedly mounted on the top portion of the top plate 1202, the second limiting plate 1204 is fixed with the sliding plate 1203 through a second nut threaded connection arranged on the top portion, and the sliding plate 1203 corresponds to a discharge hole 303 formed in an outer wall of the pressure box 3.

In still another embodiment of the present invention, further, the roller 1201 on the supporting plate 12 is used for smoothly sliding when the aluminum sheet passes through the roller 1201 after being secondarily molded by the first molding positioning cylinder 9 and the second molding positioning cylinder 10, and the second limiting plate 1204 on the top plate 1202 plays a role of guiding and limiting the aluminum sheet so that the aluminum sheet can correspond to the discharge port 303 and pass through to the outer side of the pressing box 3, wherein the distance between the two second limiting plates 1204 can be adjusted according to requirements, so as to adapt to aluminum sheets with different widths; the top plate 1202 is provided with a guide rail, and then the second limiting plate 1204 only needs one end to be slidably mounted in the top plate 1202, and the other end of the second limiting plate does not deviate in the guiding process under the condition that the second limiting plate is not slidably connected (as shown in the state of fig. 5).

As shown in fig. 3 and 12, the conveyor further includes a support 4, the support 4 is disposed on one side of the pressing box 3, the transmission mechanism includes a first linkage rod 502, a second linkage rod 504 and a third linkage rod 505, a third gear 1102 is disposed at one end of a first belt pulley 11 disposed on the conveyor body 1, the third gear 1102 is engaged with the first linkage rod 502, the first belt pulley 11 is sleeved with a second belt pulley 1001 disposed on one end of a second shaping positioning cylinder 10 through a second connecting belt 1101 disposed on an outer wall, the stepping motor 5 is fixedly disposed on the support 4, the action gear 501 is engaged with the first linkage rod 502, a first gear 503 is disposed on an outer wall of the first linkage rod 502, the first gear 503 is engaged with the second linkage rod 504, the second linkage rod 504 is engaged with the third linkage rod 505, and the third linkage rod 505 is engaged with a second gear 506 disposed on one end of the driving belt pulley 6. The motor is a stepping motor 5 and further drives a gear assembly, the number of rotation turns of the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 is controlled according to requirements through a second connecting belt 1101 and a belt pulley assembly (as shown in the state of fig. 12), positioning is realized, aluminum sheets are conveyed to the cutting mechanism in a clearance mode, the length of the aluminum sheets during cutting is controlled, the aluminum sheets are cut into sheets, and the stepping motor 5 can simultaneously drive the conveyor body 1, the first shaping positioning cylinder 9 and the second shaping positioning cylinder 10 to synchronously work; wherein, the second shaping positioning barrel 10 is sleeved with the second belt pulley 1001 through the second connecting belt 1101, when the step motor 5 starts to work, the step motor 5 engages and drives the first linkage rod 502 through the action gear 501, the first linkage rod 502 engages and drives the third gear 1102 to rotate the first belt pulley 11, and then the first belt pulley 11 synchronously drives the second belt pulley 1001 to rotate, so that the second shaping positioning barrel 10 keeps rotating clockwise 360 degrees, and simultaneously the first gear 503 engages and drives the second linkage rod 504, the second linkage rod 504 engages and drives the third linkage rod 505, so that the third linkage rod 505 engages and drives the second gear 506, and the second gear 506 drives the driving belt pulley 6 to rotate counterclockwise, and further the driven belt pulley 901 rotates through the friction drive of the first connecting belt 601, so that the first shaping positioning barrel 9 rotates 360 degrees, and thus the first shaping positioning barrel 9 keeps rotating counterclockwise when the step motor 5 works, and the second moulding location section of thick bamboo 10 keeps clockwise rotation, is convenient for carry out the secondary moulding at the cooperation of first moulding location section of thick bamboo 9 and second moulding location section of thick bamboo 10 to the aluminum sheet when, can play and let the aluminum sheet carry out the effect of sliding transport to backup pad 12.

In still another embodiment of the present invention, a baffle 2 is disposed on the top of the conveyor body 1 (as shown in fig. 10), a transverse plate 201 is disposed on the baffle 2, a first limiting plate 202 is disposed on the transverse plate 201 in a relatively sliding manner, the first limiting plate 202 is fixed on the transverse plate 201 through the top and a first nut, and the conveyor body 1 is further provided with a tensioning bearing seat 101 (as shown in fig. 11). This first limiting plate 202 is used for when the aluminum sheet is carried to conveyer body 1, carry on spacingly and play the effect of direction to the aluminum sheet of carrying, and can adjust the interval between two first limiting plates 202 according to the demand, thereby adapt to the aluminum sheet of different width, only need take off first nut during the regulation, afterwards in opposite directions or back of the body remove behind the first limiting plate 202 again with first nut threaded connection fix can, the partition through first limiting plate 202 again, make conveyer body 1 divide into two processing lines and go on simultaneously.

When the device implements, carry the aluminum sheet to pressing 3 one sides of case through conveyer body 1 earlier, first limiting plate 202 on the conveyer body 1 plays the spacing effect of direction to the aluminum sheet, and when the aluminum sheet got into and presses in the case 3, have the arch to carry out the moulding of secondary with it and flatten protruding department under the roll of first moulding location section of thick bamboo 9 and the moulding location section of thick bamboo 10 of second if the aluminum sheet surface, slide to backup pad 12 one side again after first moulding location section of thick bamboo 9 and the moulding location section of thick bamboo 10 of second again, follow discharge gate 303 roll-off at last and convey to cutting mechanism department and cut.

The embodiment of the invention also provides an aluminum sheet processing system which comprises a positioning device and a cutting mechanism which are sequentially arranged along the conveying direction, wherein the positioning device is the forming and positioning integrated aluminum sheet conveying device.

The cutting mechanism provided by the embodiment of the invention, as shown in fig. 15-23, comprises a conveyor body 1, wherein the conveyor body 1 is provided with: the cutting device comprises a bracket 14, wherein two transmission components and two cutting auxiliary plates 1409 are arranged on the bracket 14, power output ends of the two transmission components are respectively in one-to-one corresponding transmission with the two cutting auxiliary plates 1409, and the cutting auxiliary plates 1409 are connected to the power output ends through elastic members; the cutting mechanism 1303 is used for moving the cutting stroke of the cutting mechanism from one side to the other side of the aluminum sheet in the width direction, a first rack 1304 is arranged on the cutting mechanism 1303, two groups of tooth-shaped structures are symmetrically arranged on the first rack 1304, and the two tooth-shaped structures are respectively meshed with the tooth-shaped structures of the power input ends of the two transmission assemblies in a one-to-one correspondence manner; the cutting stroke of the cutting mechanism 1303 makes the first rack 1304 drive the two cutting auxiliary plates 1409 to abut against two sides of the notch on the aluminum sheet through the two transmission assemblies.

Specifically, the conveyor body 1 is disposed at a previous station of a cutting mechanism of an aluminum sheet processing system, the aluminum sheet output by the conveyor body is directly sent to the cutting mechanism 1303 for equal-size cutting, while the cutting mechanism slides to one side stroke in the width direction of the aluminum sheet (as shown in the state of fig. 16), the cutting mechanism 1303 drives a transmission component through a first rack 1304, so that the transmission component drives two cutting auxiliary plates 1409 to abut against two sides of a notch at the top of the aluminum sheet, that is, upper surfaces at two sides of the notch of the aluminum sheet, so as to press the aluminum sheet, it is to be noted that the cutting auxiliary plates 1409 preferentially contact with the top of the aluminum sheet in the stroke of the cutting mechanism 1303, and after the cutting auxiliary plates 1409 abut against the aluminum sheet, the cutting mechanism 1303 still needs to continue the stroke to cut the aluminum sheet, in order to avoid the cutting auxiliary plates 1409 to continue to press the aluminum sheet, here the cutting auxiliary, the elastic member is a fourth spring 1408, and the elastic pressure of the fourth spring 1408 is configured to be smaller than the deformation pressure of the aluminum sheet, thereby preventing the cutting assistance plate 1409 from pressing the aluminum sheet to be deformed when abutting against the aluminum sheet.

In this embodiment, the transmission assembly is used to convert the linear reciprocating stroke of the cutting mechanism 1303 into the linear reciprocating stroke of the cutting auxiliary plate 1409, and in the mechanical field, many transmission structures can achieve this, such as gear transmission, link transmission, even belt wheel transmission, etc., and those skilled in the art know the above transmission manner and do not need to describe any further.

According to the aluminum sheet cutting mechanism provided by the embodiment of the invention, when an aluminum sheet is cut, the cutting mechanism is in a rightward sliding process, and is in meshing transmission with the transmission assembly through the first rack 1304 on the outer wall, the transmission assembly enables the cutting auxiliary plate 1409 to be abutted against the upper surface of the aluminum sheet, and the top surface of the cut part of the aluminum sheet is abutted and limited, so that the aluminum sheet is not easy to deform during cutting, the cutting mechanism is convenient to cut, and the quality of the aluminum sheet cut by the cutting mechanism is improved.

In another embodiment of the present invention, as shown in fig. 15 and 16, the present invention further includes a pushing mechanism, a bottom supporting plate 1410 is slidably disposed on the bracket 14, the transmission assembly includes a poking rod 1405, that is, the mechanism that linearly moves on the transmission assembly drives the poking rod 1405 to linearly reciprocate, the other end of the poking rod 1405 is connected to the pushing mechanism, the bottom supporting plate 1410 is disposed on the pushing mechanism, the cutting stroke of the cutting mechanism 1303 enables the first rack 1304 to drive the two bottom supporting plates 1410 to support the aluminum sheet through the transmission assembly and the pushing mechanism, and the bottom supporting plate 1410 and the cutting auxiliary plate 1409 are respectively attached to two opposite sides of the aluminum sheet. When cutting mechanism 1303 in the cutting stroke, slide through drive assembly and let poker rod 1405 inconsistent with pushing mechanism, make pushing mechanism drive two bottom sprag boards 1410 and slide to the both sides department of aluminum sheet incision bottom, played the effect of support, be convenient for cut accessory plate 1409 aluminum plate and carry out the centre gripping, make aluminum plate be difficult to take place to warp when the cutting.

In still another embodiment of the present invention, it is preferable that the sliding direction of the bottom support plate 1410 is perpendicular to the conveying direction of the aluminum sheet as shown in fig. 19 (as shown in the state of fig. 18 and 19).

In still another embodiment of the present invention, as shown in fig. 18 and 21, an arc-shaped seat 15 is fixedly disposed in the bracket 14, the pushing mechanism includes a force-bearing plate 1504, a rotating block 1501, a fifth spring 1503, a connecting block 1502 and a sliding rod 1505, the force-bearing plate 1504 abuts against the poke rod 1405, the force-bearing plate 1504 is fixedly mounted on the top of the rotating block 1501, the rotating block 1501 is rotatably connected to the top of the arc-shaped seat 15, the connecting block 1502 is slidably disposed on the outer wall of the rotating block 1501, meanwhile, the bottom of the connecting block 1502 is slidably disposed in a U-shaped groove 1506 formed in the top of the arc-shaped seat 15, the fifth spring 1503 is fixedly disposed between the rotating block 1501 and the connecting block 1502, the sliding rod 1505 is slidably disposed on the end of the connecting block 1502, and one end of the. During the leftward sliding stroke of the second rack 1401, the pulling rod 1405 will abut against the inner wall of the left side of the force-bearing plate 1504 (refer to fig. 3), and then the force-bearing plate 1504 will move in an arc toward the left side in the stroke, so that the connecting block 1502 will slide on the rotating block 1501 while sliding in the U-shaped groove 1506, and thus the sliding rod 1505 will push the bottom support plate 1410 to slide toward the aluminum sheet side when sliding in the connecting block 1502, wherein when the connecting block 1502 slides to the left side in the U-shaped groove 1506 (based on the center point of the U-shaped groove 1506), the fifth spring 1503 is stretched, and when the connecting block 1502 is biased to the left in the U-shaped groove 1506, the connecting block 1502 will be pulled to the tail of the left side of the U-shaped groove 1506 under the pulling force of the fifth spring 1503, the connecting block 1502 will be rapidly displaced from the U-shaped groove 1506 to the left side by the fifth spring 1503, so that the sliding rod right side rapidly pushes the bottom support plate, it should be noted that when the connecting block 1502 slides, the bottom supporting plate 1410 is driven to start to move to one side of the aluminum sheet, one end of the bottom supporting plate 1410 is preferentially moved to the bottom of the aluminum sheet before the cutting assisting plate 1409 abuts against the surface of the aluminum sheet, and therefore when the cutting assisting plate 1409 abuts against the aluminum sheet, the bottom supporting plate 1410 is not moved to the bottom of the aluminum sheet to support the aluminum sheet, so that the aluminum sheet is pressed and deformed by the cutting assisting plate 1409, and then in a rightward sliding reset stroke of the second rack 1401, the poking rod 1405 abuts against the inner wall of the right side of the stressed plate 1504 again, and then the linkage stressed plate 1504 moves in an arc shape to the right side in the stroke, so that the sliding rod 1505 pushes the bottom supporting plate 1410 to slide to one side far from the aluminum sheet to reset when sliding in the connecting.

In still another embodiment of the present invention, as shown in fig. 15 and 16, the present invention further includes a processing table 13, a guide base 1302 is fixedly disposed on the top of the processing table 13, a cutting mechanism 1303 is slidably disposed on the guide base 1302, a support 14 is fixedly disposed on the processing table 13 and located at two sides of the cutting mechanism 1303, and a pushing mechanism is fixedly disposed in the support 14.

In still another embodiment of the present invention, the holder 14 is symmetrically provided with fixing seats 1301 at both sides, the support 4 is provided at one side of the conveyor body 1, and the press box 3 is provided at the outlet of the conveyor belt of the conveyor body 1 (as shown in the state of fig. 15).

In yet another embodiment of the present invention, as shown in fig. 16 and 17, the transmission assembly includes a first spur gear 1403, a second spur gear 1404, a second rack 1401, the cutting device comprises a first abutting block 1402, a second abutting block 1406 and a third spring 1407, wherein first racks 1304 are symmetrically arranged on the outer wall of a cutting mechanism 1303, a first straight gear 1403 and a second straight gear 1404 are arranged in a support 14 in a relatively rotating mode, the second straight gear 1404 is meshed with the first racks 1304, the second racks 1401 are arranged on the inner wall of the support 14 in a sliding mode, the first straight gear 1403 is meshed with the second racks 1401, the first abutting block 1402 is fixedly arranged on the outer wall of the second racks 1401, the second abutting block 1406 is arranged in the support 14 in a sliding mode, the second abutting block 1406 is matched with the first abutting block 1402 in a wedge mode, the third spring 1407 is arranged on the outer wall of the second abutting block 1406 in a sleeved mode, and a fourth spring 1408 is fixedly arranged between the second abutting block 1406 and a cutting auxiliary plate 1409 which is installed at the bottom in a sliding.

Specifically, when the cutting mechanism 1303 is in a cutting stroke, the cutting mechanism is meshed with and drives the second spur gear 1404 through the first rack 1304, and synchronously meshes and drives the first spur gear 1403 and the second rack 1401, so that the second rack 1401 slides on the bracket 14, the first abutting block 1402 moves to the left side to abut against the second abutting block 1406, and the second abutting block 1406 is forced to slide downwards on the bracket 14 and is linked with the cutting auxiliary plate 1409 to abut against the top of an aluminum sheet; the third spring 1407 is used for making the second abutting block 1406 slide upwards under the tension force of the third spring 1407 for resetting when the first abutting block 1402 does not apply force to the second abutting block 1406 any more (when the cutting mechanism 1303 finishes cutting the aluminum sheet and resets), and the resetting of the cutting auxiliary plate 1409 avoids collision with the aluminum sheet when the aluminum sheet is fed at the next interval.

In still another embodiment of the present invention, as shown in fig. 22, the cutting assistance plate 1409 includes a cylinder fixedly disposed at the middle of the top edge of the cutting assistance plate 1409 and guide rails symmetrically and fixedly disposed on the outer wall of the cylinder.

In still another embodiment of the present invention, as shown in fig. 23, the cutting mechanism 1303 includes a U-shaped tool holder and a cutting blade, the U-shaped tool holder includes two horizontal arms oppositely disposed and a vertical arm connecting the two horizontal arms, two ends of the cutting blade are respectively connected to the two horizontal arms, the first rack 1304 is disposed on the vertical arm, and the cutting stroke is a horizontal reciprocating stroke.

In still another embodiment provided by the present invention, an aluminum sheet processing system includes a positioning device and a cutting mechanism provided in this order along a conveying direction, the cutting mechanism being the cutting mechanism of any one of claims 1 to 9.

When the device is implemented, when an aluminum sheet is cut, in the process that the cutting mechanism 1303 slides rightwards, the first rack 1304 and the second rack 1404 on the outer wall of the cutting mechanism 1303 are in meshing transmission, the first straight gear 1403 and the second rack 1401 are in meshing transmission synchronously, the first abutting block 1402 and the second abutting block 1406 are abutted to slide downwards to enable the cutting auxiliary plate 1409 to abut against the top of the aluminum sheet, meanwhile, the first abutting block 1402 is abutted to the outer wall of the stressed plate 1504 through the poking rod 1405 in the sliding process to enable the stressed plate 1504 to move leftwards in an arc shape, further, the connecting block 1502 is linked to slide in the U-shaped groove 1506 and also slide on the rotating block 1501, the sliding rod on the connecting block 1505 pushes the bottom supporting plate 1410 to slide leftwards to enable the bottom supporting plate 1505 to be supported on the bottom of the aluminum sheet (as shown in a state in fig. 18), the device can clamp and limit the top and the bottom of two sides of the cut part of the aluminum sheet before the cutting mechanism, the aluminum sheet cutting machine is not easy to deform during cutting of an aluminum sheet, and the cutting mechanism 1303 is convenient to cut, so that the quality of the aluminum sheet cut by the cutting mechanism 1303 is improved.

The above embodiments are only exemplary embodiments of the present invention, and are not intended to limit the present invention, and the scope of the present invention is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present invention, and such modifications and equivalents should also be considered as falling within the scope of the present invention.

Claims (10)

1. The utility model provides a shaping location integral type aluminum sheet conveyor, includes conveyer body (1), its characterized in that is provided with on conveyer body (1):

the aluminum sheet conveying device comprises a first shaping positioning barrel (9) and a second shaping positioning barrel (10) which are arranged oppositely, wherein a shaping conveying space of an aluminum sheet is formed between the first shaping positioning barrel (9) and the second shaping positioning barrel (10);

the stepping motor (5) synchronously drives the first shaping positioning cylinder (9) and the second shaping positioning cylinder (10) through a transmission mechanism;

the adjusting plate (7) is connected with a first rotating shaft at the end part of the first shaping positioning cylinder (9) in a sliding mode, the sliding direction of the first rotating shaft is perpendicular to the conveying direction of the aluminum sheet, the transmission mechanism comprises a belt pulley assembly, the first rotating shaft is driven by the belt pulley assembly, and a tension pulley (803) is arranged on the belt pulley assembly;

still include conflict mechanism, conflict mechanism both ends are connected respectively regulating plate (7) with first pivot, conflict pressure of conflict mechanism is configured to be greater than the deformation pressure of aluminum sheet.

2. The forming and positioning integrated aluminum sheet conveying device according to claim 1, further comprising a pressing box (3) and a locking mechanism, wherein the adjusting plate (7) is slidably arranged in the pressing box (3), the sliding direction of the adjusting plate (7) is perpendicular to the conveying direction of the aluminum sheet, and the locking mechanism is used for locking the adjusting plate (7) into the pressing box (3) at any position.

3. The forming-positioning-integrated aluminum sheet conveying device as claimed in claim 2, wherein the first forming-positioning cylinder (9), the second forming-positioning cylinder (10) and the pulley assembly are located in the pressing box (3).

4. The forming and positioning integrated aluminum sheet conveying device as claimed in claim 1, wherein a traveling gear (501) is fixedly mounted at an output end of the stepping motor (5), the traveling gear (501) is meshed with an input gear of the transmission mechanism, and the transmission mechanism is a gear assembly.

5. The forming and positioning integrated aluminum sheet conveying device as claimed in claim 1, wherein the abutting mechanism comprises a slope block (703), a first spring (704) and a moving block (705), the slope block (703) is slidably arranged on the outer wall of the adjusting plate (7) through the moving block (705), the first spring (704) is arranged between the slope block (703) and the outer wall of the adjusting plate (7), a force-bearing block (701) is slidably arranged on the outer wall of the adjusting plate (7), a pushing block (702) is fixedly mounted at the top of the force-bearing block (701), the pushing block (702) is in wedge-shaped fit with the slope block (703), and the slope block (703) is slidably abutted to a first rotating shaft.

6. The forming and positioning integrated aluminum sheet conveying device as claimed in claim 1, wherein the pulley assembly comprises a driving pulley (6), a first connecting belt (601) and a driven pulley (901), the driving pulley (6) is rotatably connected to the inner wall of the pressing box (3), the first connecting belt (601) is sleeved on the driving pulley (6) and the driven pulley (901), the first shaping positioning cylinder (9) is fixedly installed on the driven pulley (901), and the end of the first shaping positioning cylinder (9) is rotatably connected to the stressed block (701).

7. The forming and positioning integrated aluminum sheet conveying device according to claim 2, wherein a sliding block (302) is slidably mounted on a guide plate (301) arranged on the inner wall of the pressing box (3), the adjusting plate (7) is fixedly mounted on the sliding block (302), a connecting plate (8) is arranged on the adjusting plate (7), a displacement block (802) is slidably arranged on the connecting plate (8), a second spring (801) is arranged between the displacement block (802) and the connecting plate (8), the tension wheel (803) is rotatably connected to the displacement block (802), and the tension wheel (803) vertically resists and tensions the first connecting belt (601) through the acting force exerted by the second spring (801).

8. The forming-positioning-integrated aluminum sheet conveying device as claimed in claim 5, wherein the bevel block (703) is in sliding abutment on the first forming-positioning barrel (9).

9. The forming and positioning integrated aluminum sheet conveying device according to claim 2, wherein a supporting plate (12) is arranged on the inner wall of the pressing box (3), a roller (1201) is arranged on the supporting plate (12) in a linear distribution coupling manner, a top plate (1202) is fixedly mounted at the top of the supporting plate (12), a second limiting plate (1204) is slidably mounted on the top plate (1202), a sliding plate (1203) is fixedly mounted at the top of the top plate (1202), the second limiting plate (1204) is fixedly connected with the sliding plate (1203) through a second nut and a thread, the second nut and the thread are connected with the top of the second limiting plate, and the sliding plate (1203) corresponds to a discharge hole (303) formed in the outer wall of the pressing box (3).

10. An aluminum sheet processing system comprising a positioning device and a cutting mechanism arranged in this order along a conveying direction, characterized in that the positioning device is the forming positioning integrated type aluminum sheet conveying device of any one of claims 1 to 9.

Images