CN219216787U - Artificial board stacking equipment - Google Patents

Abstract

The utility model discloses artificial board stacking equipment which comprises a rack, wherein a stacking supporting device is arranged on the rack, a board entering guide device is arranged on the rack, which is positioned on the coming board side of the stacking supporting device, and the guide surface of the board entering guide device is higher than the supporting surface of the stacking supporting device; and a plate entering buffer device is arranged on the frame and positioned at one side of the stacking supporting device, which is opposite to the plate entering guide device, and a plate aligning device is arranged on the frame. The wood-based plate is followed go into board guider input extremely pile supporting device top, in the input process, hit on the income board buffer, go into the board buffer and carry out quick buffering with the wood-based plate of input, the wood-based plate collides the deformation and reduces. And the buffered artificial boards fall onto the stacking supporting device by self weight, and are aligned by the plate alignment device. And the actions are circulated to form the artificial board high-efficiency stack.

Description

Artificial board stacking equipment

Technical Field

The utility model relates to stacking equipment, in particular to artificial board stacking equipment.

Background

The artificial board is made up by using wood or other non-wood plant as raw material, making them pass through a certain mechanical process, separating them into various unit materials, and using or not using adhesive and other additives to make them glue so as to obtain the invented artificial board or moulded product. The manufacturing of the artificial board comprises the main working procedures of cutting, drying, sizing, forming and the like, and the formed artificial board is subjected to quality detection, cooling and the like and then is uniformly stacked and output. At present, the quality detection, cooling and the like of the artificial boards form pipelining operation, and the stacking can be transported by the pipelining operation to carry out efficient stacking. However, the artificial board belongs to a large-weight board with the weight of forty-fifty kilograms, when the artificial board is sequentially input to the stacking equipment from the production line, large inertia generally exists, the collision action is obvious, if the problem of strong collision input cannot be well processed, the board is easy to collide and deform, and loss is caused, and the existing artificial board stacking equipment cannot simultaneously meet the requirements of high-efficiency stacking, high-frequency strong collision input processing and the like.

Disclosure of Invention

The utility model aims to solve the technical problem of providing artificial board stacking equipment which can be used for rapidly buffering input board pieces, reducing collision deformation of the board pieces and forming efficient stacking.

In order to solve the technical problems, the technical scheme of the utility model is as follows: the artificial board stacking equipment comprises a rack, wherein a stacking supporting device is arranged on the rack, a board entering guide device is arranged on the rack and positioned on the board coming side of the stacking supporting device, and the guide surface of the board entering guide device is higher than the supporting surface of the stacking supporting device; and a plate entering buffer device is arranged on the frame and positioned at one side of the stacking supporting device, which is opposite to the plate entering guide device, and a plate aligning device is arranged on the frame.

As an optimized technical scheme, the plate entering buffer device comprises a plate entering buffer seat arranged on the frame, a plate entering buffer cylinder is arranged on the plate entering buffer seat, and a piston rod of the plate entering buffer cylinder extends towards the plate entering guide device; and a buffer baffle is fixedly arranged at the end part of a piston rod of the plate-entering buffer cylinder.

As an optimal technical scheme, an elastic buffer is further arranged between the buffer baffle and the frame.

As a preferable technical scheme, the elastic buffer comprises a pneumatic rod connected between the buffer baffle plate and the plate-entering buffer seat.

As an optimized technical scheme, the elastic buffer comprises a buffer baffle seat which is slidably arranged on the plate-entering buffer seat, a first buffer connecting rod is arranged on the buffer baffle seat in a swinging way, a second buffer connecting rod is arranged on the plate-entering buffer seat in a swinging way, and a rubber elastic component is arranged between the free ends of the first buffer connecting rod and the second buffer connecting rod; one side of the buffer baffle seat, which is close to the buffer baffle, is provided with a buffer baffle part for the buffer baffle to baffle.

As an optimized technical scheme, the plate entering buffer seat is slidably mounted on the frame along the direction close to or far away from the plate entering guide device, and a buffer distance regulator is arranged between the plate entering buffer seat and the frame.

As an optimized technical scheme, the plate entering guide device comprises a plate entering guide roller rotatably arranged on the frame, and the plate entering guide roller is connected with a plate entering speed reducing driver; the upper part of the plate entering guide roller is movably provided with a plate entering guide pressing frame, the plate entering guide pressing frame is provided with a plate entering pressing roller which can press the plate entering guide roller, and a plate entering pressing force applicator is arranged between the plate entering guide pressing frame and the frame.

As a preferable technical scheme, the plate alignment device comprises a longitudinal alignment baffle fixedly arranged on the frame and positioned on the coming plate side of the stacking support device, a longitudinal alignment cylinder is arranged on the frame and positioned on one side of the stacking support device away from the longitudinal alignment baffle, and a longitudinal pair Ji Shili plate capable of pushing the artificial plate to move towards the longitudinal alignment baffle is arranged at the end part of a piston rod of the longitudinal alignment cylinder; the transverse alignment baffle is arranged on the side, located in the plate placement direction, of the stacking support device, the transverse alignment cylinder is arranged on the side, away from the transverse alignment baffle, of the stacking support device, and the transverse pair Ji Shili plate capable of pushing the artificial plate to move towards the transverse alignment baffle is arranged at the end part of a piston rod of the transverse alignment cylinder.

As the preferable technical scheme, two stacking supporting devices which are arranged in parallel left and right are arranged on the frame, a stacking partition board which is arranged in a vertical movable mode is arranged between the two stacking supporting devices on the frame, and a separation controller is arranged between the stacking partition board and the frame.

As an optimized technical scheme, two stacking supporting devices are sequentially arranged on the frame along the plate entering direction, and the plate entering guide device and the plate entering buffer device are respectively arranged on the frame corresponding to each stacking supporting device; a stacking and distributing frame capable of moving up and down is arranged between the two plate inlet guide devices on the frame, and a distributing and conveying device capable of conveying the artificial plate at the plate inlet guide device at the upstream to the plate inlet guide device at the downstream is arranged on the stacking and distributing frame; the upstream plate entering buffer device is arranged on the stacking and distributing frame, and the upstream plate entering buffer device is arranged below the distributing and conveying device; and a shunt controller is arranged between the stacking shunt frame and the frame.

Due to the adoption of the technical scheme, the artificial board stacking device comprises a rack, wherein a stacking supporting device is arranged on the rack, a board entering guide device is arranged on the rack and positioned on the board coming side of the stacking supporting device, and the guide surface of the board entering guide device is higher than the supporting surface of the stacking supporting device; and a plate entering buffer device is arranged on the frame and positioned at one side of the stacking supporting device, which is opposite to the plate entering guide device, and a plate aligning device is arranged on the frame. The wood-based plate is followed go into board guider input extremely pile supporting device top, in the input process, hit on the income board buffer, go into the board buffer and carry out quick buffering with the wood-based plate of input, the wood-based plate collides the deformation and reduces. And the buffered artificial boards fall onto the stacking supporting device by self weight, and are aligned by the plate alignment device. And the actions are circulated to form the artificial board high-efficiency stack.

Drawings

The following drawings are only for purposes of illustration and explanation of the present utility model and are not intended to limit the scope of the utility model. Wherein:

FIG. 1 is a schematic view of a first embodiment of the present utility model;

FIG. 2 is an enlarged schematic view of the plate entering buffer device of FIG. 1;

FIG. 3 is a schematic view of the plate loading buffer device of FIG. 2 when the artificial plate is stopped;

fig. 4 is a schematic view of the artificial board of fig. 1 in a state where the artificial board is stopped by buffering;

FIG. 5 is a schematic perspective view of an embodiment of the utility model without showing the stack support;

FIG. 6 is a schematic view of the structure of FIG. 5 at another angle;

FIG. 7 is an enlarged schematic view of the structure at A of FIG. 6;

FIG. 8 is an enlarged schematic view of the structure at B of FIG. 6;

FIG. 9 is a schematic view showing a stack of a stack support device according to an embodiment of the present utility model stacked to a designated number;

FIG. 10 is a schematic view of the structure of a stacked artificial board on a stacking support downstream of the second embodiment of the present utility model;

fig. 11 is a schematic view of a structure for stacking artificial boards on a stacking support device upstream of the second embodiment of the present utility model.

In the figure: 1-a frame; 2-stacking a supporting device; 3-a plate-entering guide device; 31-a plate-entering guide roller; 32-a plate-entering guide table; 33-a board entering speed reducing driver; 34-a plate-entering guide pressing frame; 35-plate feeding pressing roller; 36-a plate-entering pressing force applicator; 4-a plate entering buffer device; 41-a plate-entering buffer seat; 42-a plate-entering buffer cylinder; 43-buffer baffle; 44-elastic buffer; 441-a pneumatic rod; 442-a buffer baffle seat; 443-a first buffer link; 444-second buffer link; 445-rubber elastic component; 446-a bumper abutment; 45-buffer distance adjuster; 5-plate alignment means; 51-longitudinally aligned baffles; 52-a transverse alignment cylinder; 53-transverse pair Ji Shili plates; 6-stacking the separator plates; 61-partition controller; 7-stacking a shunt frame; 71-shunt controller; 9-artificial board.

Detailed Description

The utility model is further illustrated in the following, in conjunction with the accompanying drawings and examples. In the following detailed description, exemplary embodiments of the utility model are described by way of illustration only. It is needless to say that the person skilled in the art realizes that the described embodiments may be modified in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive in scope.

Embodiment one: as shown in fig. 1 to 9, the artificial board stacking apparatus includes a frame 1, where the frame 1 is a carrier of each functional device, and may be an integral frame body, or may be a generic name of separate frame bodies that are relatively fixedly arranged for installing different functional devices.

The frame 1 is provided with a stacking and supporting device 2, and the main function of the stacking and supporting device 2 is to support an input artificial board 9. Preferably, the stack supporting means 2 has a lifting function, and the height of the thickness of one artificial board 9 is lowered after each stack of the artificial boards 9, so as to match and keep the supporting surface of the artificial board 9 after entering the board unchanged. Conventionally, the stacking and supporting device 2 includes a stacking and supporting bracket, and a supporting lifting controller is disposed between the stacking and supporting bracket and the frame 1, and this structure is a common technology in the existing field of stacking and supporting of the artificial board 9, and is well known to those skilled in the art and will not be described herein.

Preferably, the stacking support bracket is provided with a stacking output mechanism capable of outputting laterally so as to integrally output the specified number of artificial boards 9 after being supported. The stack delivery device can be realized by a roller conveyor, whereby the delivery function of the stack delivery device forms the second function of the stack support device 2, while the conveyor surface of the stack delivery device also simultaneously forms the initial support surface of the stack support device 2.

The frame 1 is located the coming board side of stack supporting device 2 is equipped with into board guider 3, go into the guide surface of board guider 3 is higher than the bearing surface setting of stack supporting device 2, from this artificial board 9 warp go into after board guider 3 direction input, can reach earlier stack supporting device 2 top can not take place direct contact with stack supporting device 2, also be difficult for because of input inertia with stack supporting device 2 directly takes place to collide promptly, do benefit to the reduction and collide and warp.

The frame 1 is provided with the plate entering buffer device 4 at one side of the stack supporting device 2, which is opposite to the plate entering guide device 3, and the plate entering buffer device 4 can retract the artificial plate 9 and simultaneously generate a blocking buffer effect on the artificial plate, so that the artificial plate 9 with larger inertia can be quickly stopped, and the reaction force of the artificial plate 9 in the process is much smaller than that of the direct collision, so that the artificial plate 9 is not easy to collide and deform.

The plate entering buffer device 4 in this embodiment includes a plate entering buffer seat 41 disposed on the frame 1, a plate entering buffer cylinder 42 is mounted on the plate entering buffer seat 41, and a piston rod of the plate entering buffer cylinder 42 extends toward the plate entering guide device 3; the end of the piston rod of the plate-entering buffer cylinder 42 is fixedly provided with a buffer baffle 43. Before the artificial board 9 is input, the piston rod of the board-entering buffer cylinder 42 stretches out, when the artificial board 9 is input, the board-entering buffer cylinder 42 starts to shrink slowly, and when the artificial board 9 collides against the buffer baffle 43, the board-entering buffer cylinder 42 forms the buffer for the input of the artificial board 9 under the influence of the active shrinkage action of the board-entering buffer cylinder 42 and the change of the fluid volume between the upper cavity and the lower cavity of the board-entering buffer cylinder 42. Preferably, the buffer baffle 43 includes a rigid layer fixedly disposed on the piston rod of the plate-in buffer cylinder 42, and a soft layer fixedly disposed on the side surface of the rigid layer near the plate-in guide device 3, so that the soft layer contacts with the artificial plate 9, and collision damage can be reduced.

The plate-entering guide device 3 of the embodiment comprises a plate-entering guide roller 31 rotatably installed on the frame 1, and a plate-entering guide table 32 can be arranged on the plate-entering side of the plate-entering guide roller 31 to be matched with plate-entering guide if required; the plate entering guide roller 31 is connected with a plate entering speed reducing driver 33, the plate entering speed reducing driver 33 drives the plate entering guide roller 31 to convey at a conveying speed lower than that before the input of the artificial plate 9, so that the plate entering guide roller forms a speed reducing action on the artificial plate 9, and the plate entering speed reducing device can be matched with the plate entering buffer device 4 to further reduce damage caused by strong impact input. Conventionally, the entering plate speed reducing driver 33 is realized by a motor, a speed reducer and the like.

The plate feeding guide pressing frame 34 is movably arranged above the plate feeding guide roller 31 on the frame 1, the plate feeding pressing roller 35 capable of pressing against the plate feeding guide roller 31 is arranged on the plate feeding guide pressing frame 34, and the plate feeding pressing force applicator 36 is arranged between the plate feeding guide pressing frame 34 and the frame 1. The plate-entering holding force applicator 36 drives the plate-entering guide pressing frame 34 to press downwards, so that the plate-entering holding roller 35 reliably presses the input artificial plate 9 on the plate-entering guide roller 31, and therefore the artificial plate 9 can be stably and reliably slowed down by the plate-entering guide roller 31.

Preferably, an elastic buffer 44 is further provided between the buffer baffle 43 and the frame 1, so as to cooperate with the buffering of the plate-in buffer cylinder 42 to achieve a better buffering effect. The elastic damper 44 includes a pneumatic rod 441 connected between the damper baffle 43 and the plate-in damper seat 41, and the pneumatic rod 441 is also called a pneumatic support rod, or a pneumatic spring, etc., which is a known technology for generating an elastic action by utilizing the compressibility of gas, and will not be described herein.

In addition, the elastic buffer 44 includes a buffer stop seat 442 slidably mounted on the plate-in buffer seat 41, a first buffer link 443 is mounted on the buffer stop seat 442 in a swinging manner, a second buffer link 444 is mounted on the plate-in buffer seat 41 in a swinging manner, and a rubber elastic component 445 is mounted between the free ends of the first buffer link 443 and the second buffer link 444; the buffer stop seat 442 is provided with a buffer stop portion 446 for stopping the buffer stop plate 43 at a side close to the buffer stop plate 43. The rubber elastic component 445 is a known technology for generating elastic force by using elastic deformation of rubber, and will not be described herein. After the buffer baffle 43 is abutted against the buffer abutment 446, the buffer stop seat 442 slides away from the board entry guide 3, and the swinging of the first buffer link 443 and the second buffer link 444 drives the rubber structure of the rubber elastic assembly 445 to generate a torsional deformation, which generates a buffer force against the artificial board 9. In practical use, the above two elastic buffers 44 may be alternatively or together, and this embodiment is illustrated as being used together.

Preferably, the plate entering buffer seat 41 is slidably mounted on the frame 1 along a direction approaching or separating from the plate entering guide device 3, and a buffer distance regulator 45 is arranged between the plate entering buffer seat 41 and the frame 1. The plate-entering buffer device 4 can be suitable for buffering artificial plates 9 with different lengths. The buffer distance adjuster 45 in this embodiment includes at least two adjusting driving wheels rotatably mounted on the frame 1, where the adjusting driving wheels are disposed on sides of the plate entering buffer seat 41, which are close to and far from the plate entering guide device 3, and one end of the plate entering buffer seat 41, which is close to the plate entering guide device 3, is provided with an adjusting driving chain belt, and the adjusting driving chain belt bypasses all the adjusting driving wheels and is connected with the other end of the plate entering buffer seat 41; one of the adjusting driving wheels is connected with an adjusting motor.

Be equipped with plate alignment device 5 on frame 1, wood-based plate 9 input buffering is zero to the speed, can fall to because of the dead weight on the stack supporting device 2, at this moment plate alignment device 5 carries out the alignment of its left and right directions to reach neat stack's effect.

The plate alignment device 5 comprises a longitudinal alignment baffle plate 51 fixedly arranged on the frame 1 and positioned on the coming plate side of the stacking support device 2, a longitudinal alignment cylinder is arranged on one side, far away from the longitudinal alignment baffle plate 51, of the stacking support device 2 on the frame 1, and a longitudinal alignment Ji Shili plate capable of pushing the artificial plate 9 to move towards the longitudinal alignment baffle plate 51 is arranged at the end part of a piston rod of the longitudinal alignment cylinder. The longitudinal alignment cylinder drives the longitudinal pair Ji Shili plates to actively push and the longitudinal alignment baffle plate 51 to rigidly limit, so that the artificial boards 9 are longitudinally aligned in a stacking way. Of course, the longitudinal alignment baffle 51 is preferably arranged below the entrance plate guide 3.

Similarly, a transverse alignment baffle is installed on the side, located in the plate entering direction, of the stacking support device 2 on the frame 1, a transverse alignment cylinder 52 is installed on the side, away from the transverse alignment baffle, of the stacking support device 2 on the frame 1, and a transverse pair Ji Shili of plates 53 capable of pushing the artificial plate 9 to move towards the transverse alignment baffle is installed at the end of a piston rod of the transverse alignment cylinder 52. The transverse alignment cylinder 52 drives the transverse pair Ji Shili plates 53 to actively push and the transverse alignment baffle plate to rigidly limit, so that the transverse alignment of the artificial board 9 stack is realized.

Based on the arrangement of the plate entering buffer cylinder 42 on the opposite side of the plate entering guide device 3 in the present embodiment, the plate entering buffer cylinder 42 doubles as the longitudinal alignment cylinder, and the buffer baffle 43 doubles as the longitudinal pair Ji Shili of plates. Thus, the whole structure can be simplified, and the cost of the parts can be reduced.

Preferably, two stacking and supporting devices 2 are installed on the frame 1, a stacking partition plate 6 is installed between the two stacking and supporting devices 2, and a separation controller 61 is arranged between the stacking partition plate 6 and the frame 1. The common artificial board 9 has 1220mm and 2440mm different width sizes, and the stacking partition board 6 is utilized in the embodiment, so that the purpose of being matched with a narrow board and a wide board for use respectively is achieved, and the universality is strong.

The implementation is that when the assembly line matched with two artificial boards 9 with the width of 1220mm is used, the separation controller 61 drives the stacking baffle 6 to descend so as to separate the two stacking supporting devices 2, and the two stacking supporting devices 2 can respectively receive the artificial boards 9 input by the two assembly lines to perform stacking operation. In this case, the stacking baffle 6 also serves as a transverse alignment baffle, i.e. the two stacking support devices 2 are provided with the transverse alignment cylinders 52 and the transverse pairs Ji Shili of plates 53 on the far side respectively, and both sides push the artificial boards 9 toward the stacking baffle 6 together to realize transverse alignment. When the assembly line matched with the artificial board 9 with the width of 2440mm is used, the separation controller 61 drives the stacking baffle plates 6 to lift, and the two stacking supporting devices 2 jointly support the input artificial board 9. In this case, one of the lateral pair Ji Shili plates 53 doubles as the lateral alignment baffle, and the other lateral pair Ji Shili plate 53 pushes the artificial plate 9 toward that side to achieve lateral alignment. The partition controller 61 may be implemented by an air cylinder, an electric cylinder, or the like.

In use, the plate feeding buffer cylinder 42 of the plate feeding buffer device 4 extends before the artificial plate 9 is fed. When the artificial board 9 on the assembly line reaches the board feeding guide device 3, the board feeding pressing force applicator 36 drives the board feeding pressing roller 35 to press the artificial board 9 onto the board feeding guide roller 31, the artificial board 9 is decelerated under the deceleration action of the board feeding guide roller 31, and the collision capacity of the decelerated artificial board 9 is reduced. The plate entering buffer cylinder 42 starts to retract, the artificial plate 9 collides with the plate entering buffer cylinder 42, the plate entering buffer cylinder 42 and the elastic buffer 44 act together, the artificial plate 9 is blocked while being retracted, namely, the input of the artificial plate 9 is buffered, the artificial plate 9 is finally stopped above the stacking supporting device 2 with relatively stable deceleration acceleration, and the artificial plate 9 falls onto the stacking supporting device 2 to form a stack due to self weight. The board entering pressing roller 35 is then lifted up, and the board aligning device 5 aligns the artificial board 9 in the front-rear, left-right direction, wherein the board entering buffer cylinder 42 doubles as the longitudinal aligning cylinder to longitudinally align the artificial board 9. After alignment, the stack supporting device 2 descends by the thickness of one artificial board 9, and the upper surface of the artificial board 9 just stacked forms a new supporting surface of the stack supporting device 2. The plate-entering buffer cylinder 42 extends out in a proper direction, and the stacking action is circulated until a specified number of artificial plates 9 are stacked on the stacking support device 2 and are integrally output.

The input of the artificial board 9 is buffered by the board-in buffer device 4, and the artificial board 9 is rapidly stopped with stable deceleration acceleration by matching with the deceleration of the board-in guide device 3, the buffering deceleration effect is rapid, the reaction force to the board piece is small, the artificial board 9 is not easy to collide and deform, and the embodiment is easy to adapt to the high-frequency input of the artificial board 9 to form an efficient stack.

Embodiment two: as shown in fig. 10 and 11 in common, the present embodiment is different from the first embodiment in that: two stacking supporting devices 2 are sequentially arranged on the frame 1 along the plate entering direction, and the plate entering guide device 3 and the plate entering buffer device 4 are respectively arranged on the frame 1 corresponding to each stacking supporting device 2; a stacking and distributing frame 7 which can move up and down is arranged between the two plate inlet guide devices 3 on the frame 1, and a distributing and conveying device which can convey the artificial plate 9 at the plate inlet guide device 3 at the upstream to the plate inlet guide device 3 at the downstream is arranged on the stacking and distributing frame 7; the upstream plate entering buffer device 4 is arranged on the stacking and distributing frame 7, and the upstream plate entering buffer device 4 is arranged below the distributing and conveying device; a shunt controller 71 is arranged between the stacking shunt frame 7 and the frame 1.

When the upstream stack supporting device 2 performs stacking, the split-flow controller 71 drives the stack split-flow frame 7 to lift, and after the artificial board 9 is guided by the upstream board-entering guide device 3, the artificial board directly reaches above the upstream stack supporting device 2, and starts stacking operation. When the stacking is carried out to a specified number on the upstream stacking support device 2, the stacking diverting frame 7 is driven to descend, and the artificial boards 9 reach the upper side of the downstream stacking support device 2 from the downstream board inlet guide device 3 through the diverting and conveying device, so that stacking operation is started. During this time, the artificial boards 9 stacked on the stack pallet 2 upstream are discharged and reset after the discharge. After the stacks have been stacked to a specified number on the downstream stack pallet 2, the stack diversion shelf 7 is driven to rise again, repeating the above-described working cycle. Therefore, the embodiment realizes better connection with the high-frequency input of the assembly line, and the stacking operation efficiency is higher.

The stacking and distributing frame 7 is shown to be installed on the frame 1 in a swinging manner, and of course, one end of the stacking and distributing frame, which is close to the downstream plate entering guide device 3, is a swinging installation end. The split-flow conveying device can be realized by adopting a roller conveying mechanism or a belt conveying structure and the like. The split-flow controller 71 can be realized by adopting a cylinder or an electric cylinder with two ends connected in a hinged manner, or adopting a motor to be matched with a steel wire rope for suspension, or adopting a mode of arranging a crank on the output end of the motor, connecting rods connected with the stack split-flow frame 7 in a hinged manner on the crank, and the like.

The foregoing has shown and described the basic principles, main features and advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (10)

1. The artificial board stacking device comprises a frame and is characterized in that: the machine frame is provided with a stacking supporting device, a plate entering guide device is arranged on the machine frame and positioned on the plate coming side of the stacking supporting device, and the guide surface of the plate entering guide device is higher than the supporting surface of the stacking supporting device; and a plate entering buffer device is arranged on the frame and positioned at one side of the stacking supporting device, which is opposite to the plate entering guide device, and a plate aligning device is arranged on the frame.

2. The artificial board stacking apparatus as claimed in claim 1, wherein: the plate entering buffer device comprises a plate entering buffer seat arranged on the frame, a plate entering buffer cylinder is arranged on the plate entering buffer seat, and a piston rod of the plate entering buffer cylinder extends towards the plate entering guide device; and a buffer baffle is fixedly arranged at the end part of a piston rod of the plate-entering buffer cylinder.

3. The artificial board stacking apparatus as claimed in claim 2, wherein: an elastic buffer is arranged between the buffer baffle and the frame.

4. A wood-based plate stacking apparatus as claimed in claim 3, wherein: the elastic buffer comprises an air pressure rod connected between the buffer baffle plate and the plate-entering buffer seat.

5. A wood-based plate stacking apparatus as claimed in claim 3, wherein: the elastic buffer comprises a buffer baffle seat which is slidably arranged on the plate-entering buffer seat, a first buffer connecting rod is arranged on the buffer baffle seat in a swinging way, a second buffer connecting rod is arranged on the plate-entering buffer seat in a swinging way, and a rubber elastic component is arranged between the free ends of the first buffer connecting rod and the second buffer connecting rod; one side of the buffer baffle seat, which is close to the buffer baffle, is provided with a buffer baffle part for the buffer baffle to baffle.

6. The artificial board stacking apparatus as claimed in claim 2, wherein: the plate entering buffer seat is slidably mounted on the frame along the direction close to or far away from the plate entering guide device, and a buffer distance regulator is arranged between the plate entering buffer seat and the frame.

7. The artificial board stacking apparatus as claimed in claim 1, wherein: the plate entering guide device comprises a plate entering guide roller rotatably installed on the frame, and the plate entering guide roller is connected with a plate entering speed reducing driver; the upper part of the plate entering guide roller is movably provided with a plate entering guide pressing frame, the plate entering guide pressing frame is provided with a plate entering pressing roller which can press the plate entering guide roller, and a plate entering pressing force applicator is arranged between the plate entering guide pressing frame and the frame.

8. The artificial board stacking apparatus as claimed in claim 1, wherein: the plate alignment device comprises a longitudinal alignment baffle fixedly arranged on the frame and positioned on the incoming plate side of the stacking support device, a longitudinal alignment cylinder is arranged on the frame and positioned on one side of the stacking support device away from the longitudinal alignment baffle, and a longitudinal pair Ji Shili plate capable of pushing the artificial plate to move towards the longitudinal alignment baffle is arranged at the end part of a piston rod of the longitudinal alignment cylinder; the transverse alignment baffle is arranged on the side, located in the plate placement direction, of the stacking support device, the transverse alignment cylinder is arranged on the side, away from the transverse alignment baffle, of the stacking support device, and the transverse pair Ji Shili plate capable of pushing the artificial plate to move towards the transverse alignment baffle is arranged at the end part of a piston rod of the transverse alignment cylinder.

9. The artificial board stacking apparatus as claimed in claim 1, wherein: two stacking supporting devices which are arranged side by side left and right are arranged on the frame, a stacking partition plate which is arranged vertically and movably is arranged between the two stacking supporting devices on the frame, and a separation controller is arranged between the stacking partition plate and the frame.

10. The artificial board stacking apparatus as claimed in claim 1, wherein: two stacking supporting devices are sequentially arranged on the frame along the plate entering direction, and the plate entering guide device and the plate entering buffer device are respectively arranged on the frame corresponding to each stacking supporting device; a stacking and distributing frame capable of moving up and down is arranged between the two plate inlet guide devices on the frame, and a distributing and conveying device capable of conveying the artificial plate at the plate inlet guide device at the upstream to the plate inlet guide device at the downstream is arranged on the stacking and distributing frame; the upstream plate entering buffer device is arranged on the stacking and distributing frame, and the upstream plate entering buffer device is arranged below the distributing and conveying device; and a shunt controller is arranged between the stacking shunt frame and the frame.

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