CN210999172U - Vertically and horizontally spliced all-in-one machine - Google Patents

Abstract

The utility model discloses a the utility model provides a following technical scheme: the utility model provides a splice all-in-one moves about freely and quickly, vertically splice the body, first conveyer belt, the conveying frame, transversely splice the body and receive the board box, the both sides of vertically splicing the body are rotated respectively and are connected with left socle and right branch frame, be connected with first pivot between left socle and the right branch frame, the first servo motor of last fixedly connected with of right branch frame, the first conveyer belt of one side fixedly connected with of vertically splicing the body, one side that vertical splice body was kept away from to first conveyer belt is fixed on the conveying frame, the outside of conveying frame is fixed with the controller. The utility model discloses a set up vertical concatenation body, first conveyer belt, first pivot, vertical cutter, first servo motor, conveying frame, second servo motor, transversely splice the body, second pivot, horizontal cutter, receipts board box and second drive belt and solved the veneer concatenation in-process, artifical conveying veneer is inconvenient, and the problem of artifical conveying veneer inefficiency influence veneer concatenation production.

Description

Vertically and horizontally spliced all-in-one machine

Technical Field

The utility model relates to a concatenation machine technical field is moved about freely and quickly specifically is a concatenation all-in-one moves about freely and quickly.

Background

In the industrial production process, the longitudinal and transverse splicers are respectively used for splicing the longitudinal veneers and the transverse lines, the veneers after the longitudinal splicing are generally manually transferred to the transverse splicer, then the veneers are spliced by the transverse splicer, and in the process of the second time, workers need to transfer the veneers back and forth between the longitudinal splicer and the transverse splicer, so that a lot of inconvenience is brought to the workers, the labor amount of the workers is increased, the veneers are manually transferred, waste in transfer time is caused, the production efficiency is reduced, and in the process of manually transferring the veneers, the spliced veneers are damaged by negligence sometimes, the quality of the spliced veneers is reduced, further rework is caused, and much inconvenience is brought to veneer splicing production.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

An object of the utility model is to provide a splice all-in-one with great ease to solve the problem that proposes among the above-mentioned background art.

(II) technical scheme

In order to achieve the above object, the utility model provides a following technical scheme: a longitudinal and transverse splicing integrated machine comprises a longitudinal splicing body, a first conveying belt, a conveying frame, a transverse splicing body and a plate collecting box body, wherein a left support and a right support are respectively and rotatably connected to two sides of the longitudinal splicing body, a lifting cylinder is fixedly connected between the left support and the longitudinal splicing body, a first rotating shaft is connected between the left support and the right support, a longitudinal cutter is fixedly arranged on the first rotating shaft, a first servo motor is fixedly connected to the upper portion of the right support, a second gear is fixedly connected to the output end of the first servo motor, a first conveying belt is fixedly connected to one side of the longitudinal splicing body, one side of the first conveying belt, which is far away from the longitudinal splicing body, is fixed to the conveying frame, a controller is fixedly arranged on the outer side of the conveying frame, a first sleeve, a second sleeve and a telescopic cylinder are fixedly connected to one side of the upper portion of the conveying frame, and a first telescopic rod and a second telescopic rod are respectively sleeved in the first sleeve and the, the upper part of the connecting plate is fixedly connected with one end below the first telescopic rod and the second telescopic rod, the other side of the connecting plate is fixedly connected with the first tandem shaft and the third tandem shaft, the first tandem shaft and the second tandem shaft are respectively sleeved with a first compression roller and a second compression roller, the conveying frame is fixedly provided with a second tandem shaft and a fourth tandem shaft, the second tandem shaft and the fourth tandem shaft are respectively sleeved with a first rolling shaft and a second rolling shaft, the conveying frame is fixedly provided with a second servo motor, one side of the conveying frame parallel to the axial lead of the first tandem shaft is fixedly provided with a second conveying belt, one side of the second conveying belt far away from the conveying frame is fixedly connected with a transverse splicing body, the transverse splicing body is fixedly provided with a second rotating shaft, and the second rotating shaft is fixedly provided with a transverse cutter, one side fixedly connected with of horizontal concatenation body receives the board box, equal electric connection between first servo motor, controller, telescopic cylinder, second servo motor, third servo motor and the lifting cylinder.

Preferably, the one end and the left socle of first pivot rotate to be connected, and the other end and the right branch frame rotation of first pivot are connected, the right branch frame is run through with right branch frame connected's one end to first pivot, and first pivot extends to the first gear of the one end fixedly connected with in the right branch frame outside, first gear is connected with the meshing of second gear.

Preferably, the output end of the second servo motor, the gear fixed at one end of the second tandem shaft and the gear fixed at one end of the fourth tandem shaft are connected with each other through a chain.

Preferably, the axle center direction of first cluster axle, second cluster axle, third cluster axle and fourth cluster axle all is perpendicular in the space with the axle center direction of first pivot, and first cluster axle and third cluster axle are located the top of second cluster axle and fourth cluster axle, the axis of first cluster axle and third cluster axle is located same horizontal plane, and the axis of first cluster axle and third cluster axle is parallel to each other, the axis of second cluster axle and fourth cluster axle is located same horizontal plane, and the axis of second cluster axle and fourth cluster axle is parallel to each other.

Preferably, the bilateral symmetry of the horizontal concatenation body is provided with the support, and the support is fixed on the horizontal concatenation body, the both ends of second pivot are rotated respectively and are connected on the support, and the one end of second pivot runs through the support, the part that the second pivot extends to outside the support is fixed with the fourth gear, fixedly connected with third servo motor on the support, and third servo motor's output is fixed with the third gear, the third gear is connected with the fourth gear meshing.

Preferably, the second rotating shaft is fixedly provided with transverse cutters, the transverse cutters and the longitudinal cutters are respectively provided with multiple groups, and the transverse cutters and the longitudinal cutters are respectively distributed at equal intervals along the second rotating shaft and the first rotating shaft.

Preferably, the first sleeve, the second sleeve, the first telescopic rod, the second telescopic rod, the telescopic cylinder and the connecting plate are all provided with two, and the first sleeve, the second sleeve, the first telescopic rod, the second telescopic rod, the telescopic cylinder and the connecting plate are symmetrically distributed on two sides of the conveying frame.

(III) advantageous effects

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model is provided with a longitudinal splicing body, a first transmission belt, a transmission frame, a second transmission belt, a transverse splicing body and a plate collecting box body, the veneers spliced by the longitudinal splicing body are sent into the conveying frame through the first conveying belt, the veneers are conveyed to the first rolling shaft and the second rolling shaft, the second servo motor drives the first rolling shaft and the second rolling shaft to rotate, the telescopic cylinder drives the connecting plate to move downwards, and then the first compression roller and the second compression roller are pressed on the veneers, the veneer is conveyed to a second conveyor belt under the drive of the first roller and the second roller, and then is conveyed to the transverse splicing body by the second conveyor belt, finally, the wood veneer is conveyed to the plate collecting box body through the second conveyor belt to be collected, so that the production process of integrating longitudinal splicing and transverse splicing in the production process is realized, the production process is accelerated, and the wood veneer splicing quality is ensured.

2. The utility model discloses a set up vertical concatenation body, first pivot, vertical cutter, first servo motor, transversely splice the body, the second pivot, horizontal cutter and second servo motor, in the production process, first servo motor drives first pivot and rotates, first pivot drives vertical cutter and rotates, third servo motor drives the second pivot and rotates, the second pivot drives horizontal cutter and rotates, the veneer is by the even cutting of vertical cutter after vertically splicing the body concatenation, the veneer after transversely splicing the body concatenation is cut by horizontal cutter, the cutting of the integrative word of veneer in the production process has been realized, make the veneer that finally obtains more even, high efficiency cutting veneer has, the function of improvement veneer production quality.

Drawings

FIG. 1 is an overall structure diagram of the present invention;

FIG. 2 is a side view of a portion of the transfer frame drive mechanism of the present invention;

FIG. 3 is a front view of the longitudinal split joint of the present invention;

FIG. 4 is an enlarged view of the structure at the position A of the present invention;

fig. 5 is an enlarged view of the structure of the utility model B.

The reference numbers in the figures are: 1. a longitudinal splice; 2. a first conveyor belt; 3. a first rotating shaft; 4. a longitudinal cutter; 5. a first servo motor; 6. a right bracket; 7. a first gear; 8. a second gear; 9. a controller; 10. A first press roll; 11. a transport frame; 12. a first roller; 13. a second press roll; 14. a telescopic cylinder; 15. a second servo motor; 16. a chain; 17. a second roller; 18. a transverse splice; 19. a support; 20. a second rotating shaft; 21. a transverse cutter; 22. a plate collecting box body; 23 a third servo motor; 24. a third gear; 25. a fourth gear; 26. a first sleeve; 27. a first telescopic rod; 28. a connecting plate; 29. a first tandem shaft; 30. a second tandem shaft; 31. a second sleeve; 32. a second telescopic rod; 33. a third tandem shaft; 34. a fourth tandem shaft; 35. a lifting cylinder; 36. a left bracket; 37. a second conveyor belt.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides an embodiment: a longitudinal and transverse splicing integrated machine comprises a longitudinal splicing body 1, a first conveying belt 2, a conveying frame 11, a transverse splicing body 18 and a plate collecting box body 22, wherein a left support 36 and a right support 6 are respectively and rotatably connected to two sides of the longitudinal splicing body 1, a lifting cylinder 35 is fixedly connected between the left support 36 and the longitudinal splicing body 1 and between the right support 6 and the longitudinal splicing body 1 for adjusting the positions of the left support 36 and the right support 6, a first rotating shaft 3 is connected between the left support 36 and the right support 6, a longitudinal cutter 4 is fixed on the first rotating shaft 3 and used for cutting a longitudinally spliced veneer, a first servo motor 5 is fixedly connected to the upper part of the right support 6, the type of the first servo motor 5 is IHSS57-36-20, the prior art is provided, a second gear 8 is fixedly connected to the output end of the first servo motor 5, the first conveying belt 2 is fixedly connected to one side of the longitudinal splicing body 1, the device is used for conveying veneers coming out of a longitudinal splicing body 1 to a conveying frame 11, one side, far away from the longitudinal splicing body 1, of a first conveying belt 2 is fixed on the conveying frame 11, a controller 9 is fixed on the outer side of the conveying frame 11, the model of the controller 9 is S7-400, in the prior art, one side of the upper portion of the conveying frame 11 is fixedly connected with a first sleeve 26, a second sleeve 31 and a telescopic cylinder 14, a first telescopic rod 27 and a second telescopic rod 32 are respectively sleeved in the first sleeve 26 and the second sleeve 31, the first telescopic rod 27 and the second telescopic rod 32 can respectively slide in the first sleeve 26 and the second sleeve 31, the telescopic end portion of the telescopic cylinder 14 penetrates through the upper portion of the conveying frame 11, the model of the telescopic cylinder 14 is TGC63X75, in the prior art, the telescopic end portion of the telescopic cylinder 14 is fixedly connected with a connecting plate 28, the upper portion of the connecting plate 28 is fixedly connected with one end below the first telescopic rod 27, the other side of the connecting plate 28 is fixedly connected with the first string shaft 29 and the third string shaft 33, the connecting plate 28 is used for connecting the telescopic cylinder 14 with the first pressing roller 10 and the second pressing roller 13, so that the first pressing roller 10 and the second pressing roller 13 can press the veneer through movement, the first pressing roller 10 and the second pressing roller 13 are respectively sleeved on the first string shaft 29 and the second string shaft 30, the second string shaft 30 and the fourth string shaft 34 are fixed on the transmission frame 11, the first roller 12 and the second roller 17 are respectively sleeved on the second string shaft 30 and the fourth string shaft 34, the first roller 12 and the second roller 17 respectively rotate synchronously along with the rotation of the second string shaft 30 and the fourth string shaft 34, the second servo motor 15 is fixed on the transmission frame 11, the model of the second servo motor 15 is IHSS57-36-20, as the prior art, a second conveyor belt 37 is fixed on one side of the transmission frame 11, which is parallel to the axial lead of the first string shaft 29, the wood veneer conveying device is used for conveying wood veneers in the conveying frame 11 to the transverse splicing body 18, the second conveying belt 37 is far away from the transverse splicing body 18 of one side fixedly connected with of the conveying frame 11, a second rotating shaft 20 is fixed on the transverse splicing body 18, a transverse cutter 21 is fixed on the second rotating shaft 20, a plate collecting box body 22 is fixedly connected to one side of the transverse splicing body 18 and used for collecting the wood veneers after splicing and cutting, the first servo motor 5, the controller 9, the telescopic cylinder 14, the second servo motor 15, the third servo motor 23 and the lifting cylinder 35 are electrically connected, and therefore production of longitudinal and transverse splicing integration is guaranteed.

Further, the one end and the left socle 36 of first pivot 3 rotate to be connected, and the other end and the right branch frame 6 of first pivot 3 rotate to be connected, right branch frame 6 is run through to the one end that first pivot 3 is connected with right branch frame 6, and first pivot 3 extends to the first gear 7 of the one end fixedly connected with in the right branch frame 6 outside, first gear 7 is connected with the meshing of second gear 8, first servo motor 5 drives first pivot 3 through the gear engagement transmission and rotates, and then drives vertical cutter 4 and rotates, be used for carrying out the uniform cutting to the veneer after vertically splicing.

Further, the output end of the second servo motor 15, the gear fixed at one end of the second tandem axle 30 and the gear fixed at one end of the fourth tandem axle 34 are connected with each other through a chain 16, and the second servo motor 15 drives the second tandem axle 30 and the fourth tandem axle 34 to rotate through the chain 16, so as to drive the first roller 12 and the second roller 17 to rotate.

Further, the axial directions of the first string shaft 29, the second string shaft 30, the third string shaft 33 and the fourth string shaft 34 are all perpendicular to the axial direction of the first rotating shaft 3 in space, the first string shaft 29 and the third string shaft 33 are located above the second string shaft 30 and the fourth string shaft 34, the central axes of the first string shaft 29 and the third string shaft 33 are located on the same horizontal plane, the central axes of the first string shaft 29 and the third string shaft 33 are parallel to each other, the central axes of the second string shaft 30 and the fourth string shaft 34 are located on the same horizontal plane, the central axes of the second string shaft 30 and the fourth string shaft 34 are parallel to each other, and the wood skin can be smoothly conveyed to the transverse splicing body 18 from the longitudinal splicing body 1 in the process of conveying the wood skin to the transverse splicing body 1, so that the wood skin can smoothly enter the transverse splicing body to be transversely spliced, and the longitudinal and transverse splicing integration of the wood skin is realized.

Further, supports 19 are symmetrically arranged on two sides of the transverse splicing body 18, the supports 19 are fixed on the transverse splicing body 18, two ends of a second rotating shaft 20 are rotatably connected to the supports 19 respectively, one end of the second rotating shaft 20 penetrates through the supports 19, a fourth gear 25 is fixed to the portion, extending out of the supports 19, of the second rotating shaft 20, a third servo motor 23 is fixedly connected to the supports 19, the type of the third servo motor 23 is IHSS57-36-20, the transverse splicing body is the prior art, a third gear 24 is fixed to the output end of the third servo motor 23, the third gear 24 is meshed with the fourth gear 25, and under the driving of the third servo motor 23, the second rotating shaft 20 rotates to further drive the transverse cutter 21 to rotate, so that the veneer cutting is achieved.

Further, be fixed with horizontal cutter 21 on the second pivot 20, horizontal cutter 21 and vertical cutter 4 all are provided with the multiunit, and horizontal cutter 21 and vertical cutter 4 distribute along second pivot 20 and first pivot 3 equidistant respectively, can carry out even cutting with the veneer after vertically spliceing body 1 and the concatenation of horizontal spliceing body 18 respectively.

Further, first sleeve 26, second sleeve 31, first telescopic link 27, second telescopic link 32, telescopic cylinder 14 and connecting plate 28 all are provided with two, and first sleeve 26, second sleeve 31, first telescopic link 27, second telescopic link 32, telescopic cylinder 14 and connecting plate 28 symmetric distribution are in the both sides of conveying frame, telescopic cylinder 14 drives first telescopic link 27 and second telescopic link 32 downstream, thereby drive connecting plate 28 downstream, realize that first compression roller 10 and second compression roller 13 downstream extrude the veneer.

The working principle is as follows: when the wood veneer cutting machine is used, the controller 9, the first servo motor 5, the telescopic cylinder 14, the second servo motor 15, the third servo motor 23 and the lifting cylinder 35 are connected with an external power supply and electrified, wood veneers are placed into the longitudinal splicing body 1, the wood veneers are spliced and then come out of the longitudinal splicing body 1, the first servo motor 5 rotates to drive the first rotating shaft 3 to rotate so as to drive the longitudinal cutter 4 to rotate to cut the wood veneers, the cut wood veneers are transmitted into the transmission frame 11 through the first transmission belt 2, the second servo motor 15 rotates to drive the first rolling shaft 12 and the second rolling shaft 17 to rotate, under the control action of the controller 9, the telescopic cylinder 14 drives the first telescopic rod 27 and the second telescopic rod 32 to move downwards so as to drive the connecting plate 28 to move downwards, finally, the first compression roller 10 and the second compression roller 13 are driven to move downwards to compress the wood veneers, the wood veneers are transmitted onto the second transmission belt 37 under the drive of the first rolling shaft 12 and the second rolling shaft 17, and a second conveyor belt 37 is conveyed into the transverse splicing body 18 for transverse splicing, then the third servo motor 23 drives the second rotating shaft 20 to rotate, further drives the transverse cutter 21 to cut the transversely spliced veneer, and finally the transversely cut veneer is conveyed into the board collecting box 22 through the second conveyor belt 37 for collection.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a move about freely and quickly concatenation all-in-one, vertical concatenation body (1), first conveyer belt (2), conveying frame (11), horizontal concatenation body (18) and receipts board box (22), its characterized in that: the two sides of the longitudinal splicing body (1) are respectively and rotatably connected with a left support (36) and a right support (6), a lifting cylinder (35) is fixedly connected between the left support (36) and the right support (6) and the longitudinal splicing body (1), a first rotating shaft (3) is connected between the left support (36) and the right support (6), a longitudinal cutter (4) is fixed on the first rotating shaft (3), a first servo motor (5) is fixedly connected to the upper side of the right support (6), a second gear (8) is fixedly connected to the output end of the first servo motor (5), a first conveying belt (2) is fixedly connected to one side of the longitudinal splicing body (1), one side, far away from the longitudinal splicing body (1), of the first conveying belt (2) is fixed on the conveying frame (11), a controller (9) is fixed to the outer side of the conveying frame (11), a first sleeve (26) is fixedly connected to one side of the upper portion of the conveying frame (11), A second sleeve (31) and a telescopic cylinder (14), wherein a first telescopic rod (27) and a second telescopic rod (32) are respectively sleeved in the first sleeve (26) and the second sleeve (31), the telescopic end part of the telescopic cylinder (14) penetrates through the upper part of the conveying frame (11), the telescopic end part of the telescopic cylinder (14) is fixedly connected with a connecting plate (28), the upper part of the connecting plate (28) is fixedly connected with one end below the first telescopic rod (27) and the second telescopic rod (32), the other side of the connecting plate (28) is fixedly connected with a first string shaft (29) and a third string shaft (33), the first string shaft (29) and the second string shaft (30) are respectively sleeved with a first pressing roller (10) and a second pressing roller (13), the conveying frame (11) is fixedly provided with a second string shaft (30) and a fourth string shaft (34), and the second string shaft (30) and the fourth string shaft (34) are respectively sleeved with a first rolling shaft (12) and a second rolling shaft (17), the conveying mechanism is characterized in that a second servo motor (15) is fixed on the conveying frame (11), a second conveying belt (37) is fixed on one side, parallel to the axial lead of the first string shaft (29), of the conveying frame (11), a transverse splicing body (18) is fixedly connected to one side, far away from the conveying frame (11), of the second conveying belt (37), a second rotating shaft (20) is fixed on the transverse splicing body (18), a transverse cutter (21) is fixed on the second rotating shaft (20), a plate collecting box body (22) is fixedly connected to one side of the transverse splicing body (18), and the first servo motor (5), the controller (9), the telescopic cylinder (14), the second servo motor (15), the third servo motor (23) and the lifting cylinder (35) are electrically connected.

2. The longitudinal and transverse splicing all-in-one machine as claimed in claim 1, wherein: the one end and the left socle (36) of first pivot (3) rotate to be connected, and the other end and the right branch frame (6) of first pivot (3) rotate to be connected, right branch frame (6) is run through to the one end that first pivot (3) and right branch frame (6) are connected, and first pivot (3) extend to the first gear (7) of one end fixedly connected with in the right branch frame (6) outside, first gear (7) are connected with second gear (8) meshing.

3. The longitudinal and transverse splicing all-in-one machine as claimed in claim 1, wherein: the output end of the second servo motor (15) is connected with a gear fixed at one end of the second tandem shaft (30) and a gear fixed at one end of the fourth tandem shaft (34) through a chain (16).

4. The longitudinal and transverse splicing all-in-one machine as claimed in claim 1, wherein: the axle center direction of first cluster axle (29), second cluster axle (30), third cluster axle (33) and fourth cluster axle (34) all is perpendicular in the space with the axle center direction of first pivot (3), and first cluster axle (29) and third cluster axle (33) are located the top of second cluster axle (30) and fourth cluster axle (34), the axis of first cluster axle (29) and third cluster axle (33) is located same horizontal plane, and the axis of first cluster axle (29) and third cluster axle (33) is parallel to each other, the axis of second cluster axle (30) and fourth cluster axle (34) is located same horizontal plane, and the axis of second cluster axle (30) and fourth cluster axle (34) is parallel to each other.

5. The longitudinal and transverse splicing all-in-one machine as claimed in claim 1, wherein: the bilateral symmetry of horizontal concatenation body (18) is provided with support (19), and support (19) are fixed on horizontal concatenation body (18), the both ends of second pivot (20) rotate respectively and connect on support (19), and the one end of second pivot (20) runs through support (19), the part that second pivot (20) extend to support (19) outer is fixed with fourth gear (25), fixedly connected with third servo motor (23) on support (19), and the output of third servo motor (23) is fixed with third gear (24), third gear (24) are connected with fourth gear (25) meshing.

6. The longitudinal and transverse splicing all-in-one machine as claimed in claim 1, wherein: the cutting device is characterized in that transverse cutters (21) are fixed on the second rotating shaft (20), multiple groups of transverse cutters (21) and multiple groups of longitudinal cutters (4) are arranged, and the transverse cutters (21) and the longitudinal cutters (4) are distributed at equal intervals along the second rotating shaft (20) and the first rotating shaft (3) respectively.

7. The longitudinal and transverse splicing all-in-one machine as claimed in claim 1, wherein: the conveying frame is characterized in that the number of the first sleeve (26), the number of the second sleeve (31), the number of the first telescopic rod (27), the number of the second telescopic rod (32), the number of the telescopic cylinder (14) and the number of the connecting plate (28) are two, and the first sleeve (26), the second sleeve (31), the number of the first telescopic rod (27), the number of the second telescopic rod (32), the number of the telescopic cylinder (14) and the connecting plate (28) are symmetrically distributed on two sides of the conveying frame (11).

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