CN116619488A - Board cutting device for producing multilayer solid wood composite floor - Google Patents

Abstract

The invention discloses a plate cutting device for producing a multilayer solid wood composite floor, which can realize an automatic processing working mode of a plate by adopting a mode of continuous rotation conveying, automatic clamping and multi-section cutting to automatically cut the plate, so that the complex operation of marking, positioning and repeated cutting is avoided, the plate processing mode is simplified, the labor is saved, and meanwhile, the plate cutting can complete multi-section cutting at one time, thereby effectively improving the working efficiency; including the cutting part that is located the upside and the transport portion that is located the downside, transport portion includes rotary drum and back shaft, and back shaft axis level, rotary drum rotate install on the back shaft and support the rotary drum through the back shaft, have the multiunit annular frid in proper order along back shaft axis direction on the back shaft outer wall of rotary drum inboard.

Description

Board cutting device for producing multilayer solid wood composite floor

Technical Field

The invention relates to the technical field of cutting equipment, in particular to a plate cutting device for producing a multilayer solid wood composite floor.

Background

The multilayer composite floor takes a multilayer plywood as a base material, the surface layer is a hard wood sheet embedded board or a sliced veneer, the glue is used for hot pressing, the number of layers of the base layer plywood is seven or nine, the surface layer is a hard wood surface board, the wood floor needs to be cut into boards with specified width during processing so as to be spliced later, the traditional cutting mode is to measure specified size and mark the long boards through calipers firstly, then workers place the marked long boards at the positions of the cutting sheets and repeatedly cut the marking positions of each position through the cutting sheets, the cutting mode is complicated, frequent and repeated positioning marking work and pushing cutting work are needed, the labor consumption is high, the cutting speed is low, and the working efficiency is low.

Disclosure of Invention

In order to solve the technical problems, the invention provides a plate cutting device for producing a multilayer solid wood composite floor.

In order to achieve the above purpose, the technical scheme adopted by the invention is as follows:

the plate cutting device for producing the multilayer solid wood composite floor comprises a cutting part positioned at the upper side and a conveying part positioned at the lower side, wherein the conveying part comprises a rotary drum and a supporting shaft, the axis of the supporting shaft is horizontal, the rotary drum is rotatably arranged on the supporting shaft and supports the rotary drum through the supporting shaft, a plurality of groups of annular groove plates are sequentially arranged on the outer wall of the supporting shaft at the inner side of the rotary drum along the axis direction of the supporting shaft, each group of annular groove plates consists of two annular groove plates, the annular groove plates are sleeved and fixed on the outer wall of the supporting shaft, the directions of the two annular groove plates are opposite, the top of each annular groove plate is horizontal, a plurality of slide columns are slidably clamped in each group of annular groove plates, right-angle clamping plates are arranged on the slide columns, the outer ends of the right-angle clamping plates penetrate through the rotary drum and slidably extend to the outer side of the rotary drum, and the right-angle positions of the right-angle clamping plates are positioned at the outer side of the rotary drum;

the cutting part consists of a plurality of cutting sheets which are distributed at equal intervals.

Preferably, the right angle splint comprises first subplate, second subplate and push pedal, and first subplate and traveller fixed connection, second subplate and first subplate sliding connection to through first leaf spring elastic connection between second subplate and the first subplate, the second subplate passes the rotary drum and slides relatively, and the push pedal sets up on the second subplate tip in the rotary drum outside.

Preferably, the one side of push pedal towards the rotary drum outer wall is from last to establishing gradually as clamp face, inclined plane and spacing face down, and clamp face and spacing face are all perpendicular with the second vice board, and the outer end slope and the slidable mounting of second vice board are on the inclined plane, pass through second leaf spring elastic connection between push pedal and the second vice board.

Preferably, the opening has been seted up at the push pedal middle part, is equipped with the support cover on the inboard second auxiliary plate terminal surface of opening, and the support cover extends to the outside of push pedal, is equipped with the slide bar on the support cover, and the one end of slide bar passes the support cover and slides relatively to the slide bar passes through third leaf spring elastic connection with the support cover, and the slide bar is perpendicular with the second auxiliary plate, and the other end slope of slide bar articulates there is the arc, and the outer end slope of arc articulates there is the buckle, and the tip of buckle articulates on the outer terminal surface of push pedal.

Preferably, a plurality of rows of shielding plates are annularly arranged on the outer wall of the rotary drum, each row of shielding plates is along the axis direction of the rotary drum, each row of shielding plates consists of a plurality of shielding plates, and the surfaces of the shielding plates face to the push plate;

technological openings are formed in the outer wall of the rotary drum between two adjacent shielding plates in each row of shielding plates.

Preferably, the cutting part further comprises two substrates which are oppositely arranged, the bottom of each substrate is rotatably provided with a swinging disc, a square column is fixed between the two swinging discs, a plurality of extension arms are arranged on the square column, and the cutting piece is rotatably arranged on the extension arms;

one of them is fixed with the fixed plate on the base plate, is fixed with first motor on the fixed plate, and the output of first motor is equipped with the connecting rod, and the outer end of connecting rod is equipped with pushes away the post, pushes away the post and eccentric with the output of first motor, has seted up the spout along its radial direction on the lateral wall of wobble plate, pushes away the outer end slidable mounting of post in the spout.

Preferably, the cutting machine further comprises a second motor, the second motor is arranged on one swinging disc, the output end of the second motor is provided with a first worm, the first worm is rotatably arranged between the two swinging discs, the first worm penetrates through the extension arm and slides relatively, a plurality of first worm gears are meshed on the first worm, a second worm is arranged on the first worm gear in a transmission mode, the second worm is rotatably arranged on the extension arm, the outer end of the second worm is provided with a second worm gear, and the second worm gear is in transmission connection with the cutting piece.

Preferably, the device further comprises a translation plate, wherein the translation plate is positioned at the bottom of the extension arm, the end part of the translation plate is slidably arranged on the side wall of the swinging disc, the sliding direction of the translation plate is parallel to the length direction of the extension arm, a plurality of guide grooves are formed in the translation plate, the guide grooves incline, an adjusting column is slidably arranged in the guide grooves, the adjusting column is fixed on the extension arm, an air cylinder is fixed on the swinging disc, and the output end of the air cylinder is connected with the translation plate;

the extension arm slides on the square column, and the translation board is moved a plurality of guide slots of accessible incline state and is promoted a plurality of regulation posts synchronous motion to the distance remains equally all the time between two adjacent regulation posts, thereby realizes the equidistant purpose that removes of a plurality of regulation posts.

Preferably, a third motor is fixed on the outer wall of the supporting shaft, a driving wheel is driven at the output end of the third motor, a driving ring is arranged on the end face of the rotary drum, and the driving wheel is in driving connection with the driving ring.

Compared with the prior art, the invention has the beneficial effects that: through adopting rotatory continuous transport, automatic centre gripping, multistage cutting's mode to carry out automatic cutting to panel and handle, can realize the automatic processing mode of panel, avoided needing mark location and repeated cutting's loaded down with trivial details operation, simplified panel processing mode, use manpower sparingly, panel cutting can once only accomplish multistage cutting simultaneously, has effectively improved work efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings may be obtained according to the drawings without inventive effort to those skilled in the art.

FIG. 1 is a schematic diagram of the front view of the present invention;

FIG. 2 is an enlarged schematic view of the conveying section of FIG. 1;

FIG. 3 is a schematic view of the transfer drum of FIG. 2;

FIG. 4 is a schematic cross-sectional view of the transfer drum of FIG. 2;

FIG. 5 is an enlarged schematic view of the annular channel plate and its upper structure of FIG. 4;

FIG. 6 is an enlarged schematic view of the push plate and structure thereon of FIG. 5;

FIG. 7 is an enlarged schematic view of the cutting portion of FIG. 1;

FIG. 8 is a schematic view of the bottom structure of FIG. 7;

the reference numerals in the drawings: 1. a rotating drum; 2. a support shaft; 3. an annular groove plate; 4. a spool; 5. a right angle clamping plate; 6. cutting the sheet; 7. a first sub-plate; 8. a second sub-plate; 9. a push plate; 10. a first leaf spring; 11. clamping surfaces; 12. an inclined plane; 13. a limiting surface; 14. a second leaf spring; 15. a notch; 16. a support sleeve; 17. a slide bar; 18. a third leaf spring; 19. an arc-shaped plate; 20. a buckle plate; 21. a shutter; 22. a process port; 23. a substrate; 24. a swinging disc; 25. square columns; 26. an extension arm; 27. a fixing plate; 28. a first motor; 29. a connecting rod; 30. pushing a column; 31. a second motor; 32. a first worm; 33. a first worm wheel; 34. a second worm; 35. a second worm wheel; 36. a translation plate; 37. an adjusting column; 38. a cylinder; 39. a third motor; 40. a driving wheel; 41. a drive ring.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

In the description of the present invention, it should be noted that the directions or positional relationships indicated as being "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are directions or positional relationships based on the drawings are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements to be referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; the connection may be direct or indirect via an intermediate medium, or may be internal communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art. This example was written in a progressive manner.

As shown in fig. 1 to 5, the plate cutting device for producing the multi-layer solid wood composite floor comprises a cutting part positioned at the upper side and a conveying part positioned at the lower side, wherein the conveying part comprises a rotary drum 1 and a support shaft 2, the axis of the support shaft 2 is horizontal, the rotary drum 1 is rotatably arranged on the support shaft 2 and supports the rotary drum 1 through the support shaft 2, a plurality of groups of annular groove plates 3 are sequentially arranged on the outer wall of the support shaft 2 on the inner side of the rotary drum 1 along the axis direction of the support shaft 2, each group of annular groove plates 3 consists of two annular groove plates 3, the annular groove plates 3 are sleeved and fixed on the outer wall of the support shaft 2, the directions of the two annular groove plates 3 are opposite, the top of the annular groove plates 3 is horizontal, a plurality of slide columns 4 are clamped in each group of annular groove plates 3 in a sliding manner, right-angle clamping plates 5 are arranged on the slide columns 4, the outer ends of the right-angle clamping plates 5 penetrate through the rotary drum 1 and slide out to the outer side of the rotary drum 1, and the right-angle positions of the clamping plates 5 are positioned on the outer side of the rotary drum 1;

the cutting part consists of a plurality of equally spaced cutting blades 6.

Specifically, a plurality of right angle splint 5 in the rotary drum 1 outside are the annular group and become the multiunit, and every group right angle splint 5 comprises a plurality of right angle splint 5 to every group right angle splint 5 all arrange along the axis direction of back shaft 2, because the right angle position of right angle splint 5 is located the outside of rotary drum 1, the right angle position of right angle splint 5 constitutes the U type with the outer wall of rotary drum 1, and the U type opening of rotary drum 1 one side is down, and the U type opening of the opposite side of rotary drum 1 is upwards, and during the material loading, the extension board is from the rotary drum 1 one side material loading that the U type opening was upwards, and the panel after the cutting is at the rotary drum 1 one side unloading that the U type opening was down.

When the device is operated, a long plate is placed on a plurality of right-angle clamping plates 5 on the outer side of the rotary drum 1, the rotary drum 1 is rotated, the rotary drum 1 drives the sliding column 4 to slide between two annular groove plates 3 through the right-angle clamping plates 5, because the tops of the annular groove plates 3 are horizontal, when the sliding column 4 slides to the position, the distance between the sliding column 4 and the inner wall of the rotary drum 1 is increased, at the moment, the sliding column 4 pulls the right-angle clamping plates 5 to slide on the rotary drum 1, the right-angle position of the right-angle clamping plates 5 is close to the outer wall of the rotary drum 1 and carries out automatic holding locking work on the long plate, when the long plate rotates to the top position of the rotary drum 1, the long plate between two adjacent right-angle clamping plates 5 is cut through the cutting pieces 6 of the cutting part, the plurality of cutting pieces 6 are synchronously cut, so that the long plate is cut into a plurality of plates at one time, the rotary drum 1 continues to rotate, the sliding column 4 moves towards the left side of the top of the annular groove plates 3, at the right-angle position of the right-angle clamping plates 5 is gradually away from the outer wall of the rotary drum 1, the right-angle clamping plates 5 stops clamping work on the cut plate, and the outer wall of the rotary drum 1 naturally slides to the outside conveyor belt, and thus the automatic cutting work mode of the plate is completed.

The drum 1 is continuously rotated so that the long plate can be continuously cut.

Through adopting rotatory continuous transport, automatic centre gripping, multistage cutting's mode to carry out automatic cutting to panel and handle, can realize the automatic processing mode of panel, avoided needing mark location and repeated cutting's loaded down with trivial details operation, simplified panel processing mode, use manpower sparingly, panel cutting can once only accomplish multistage cutting simultaneously, has effectively improved work efficiency.

Preferably, as shown in fig. 5, the right angle clamping plate 5 is composed of a first auxiliary plate 7, a second auxiliary plate 8 and a push plate 9, the first auxiliary plate 7 is fixedly connected with the sliding column 4, the second auxiliary plate 8 is slidably connected with the first auxiliary plate 7, the second auxiliary plate 8 is elastically connected with the first auxiliary plate 7 through a first plate spring 10, the second auxiliary plate 8 penetrates through the rotary drum 1 and slides relatively, and the push plate 9 is arranged on the end part of the second auxiliary plate 8 outside the rotary drum 1.

Specifically, through adopting the mode of combination, can make things convenient for processing and maintenance to change, simultaneously through making first subplate 7 and second subplate 8 pass through first leaf spring 10 elastic connection, when the traveller 4 moves at annular trough plate 3 top horizontal part, first subplate 7 and second subplate 8 can provide buffer space to push pedal 9, when push pedal 9 centre gripping panel, the traveller 4 still can stimulate first subplate 7 and slide on second subplate 8, first leaf spring 10 takes place elastic deformation this moment, thereby the operating condition that push pedal 9 can be for panel centre gripping stipulation time has been formed, avoid when traveller 4 and push pedal 9 hard connection, only when traveller 4 moves to the furthest with rotary drum 1 inner wall, push pedal 9 can only contact with the panel, and this clamping condition can only last one instantaneous, can not provide sufficient time for cutting work.

By adopting the structure mode of the first auxiliary plate 7, the second auxiliary plate 8 and the first plate spring 10, the plates with different thicknesses can be clamped.

Preferably, as shown in fig. 6, a surface of the push plate 9 facing the outer wall of the rotary drum 1 is sequentially provided with a clamping surface 11, an inclined surface 12 and a limiting surface 13 from top to bottom, the clamping surface 11 and the limiting surface 13 are perpendicular to the second auxiliary plate 8, the outer end of the second auxiliary plate 8 is inclined and slidably mounted on the inclined surface 12, and the push plate 9 and the second auxiliary plate 8 are elastically connected through a second plate spring 14.

Specifically, the second leaf spring 14 provides elastic thrust to push plate 9, spacing face 13 carries out the card and keeps off to second subplate 8, when second subplate 8 pulling push plate 9 moves towards rotary drum 1 outer wall direction, the clamp face 11 on push plate 9 contacts with the panel, because second subplate 8 and inclined plane 12 sliding connection this moment, the effort slope of second subplate 8 to push plate 9 to make panel backward push plate 9 slide downwards on second subplate 8, second leaf spring 14 takes place elastic deformation, thereby make clamp face 11 produce the extrusion force towards rotary drum 1 outer wall direction and the frictional force towards second subplate 8 direction to panel, improve panel fixed strength.

Preferably, as shown in fig. 6, the middle of the push plate 9 is provided with a notch 15, the end surface of the second auxiliary plate 8 on the inner side of the notch 15 is provided with a supporting sleeve 16, the supporting sleeve 16 extends to the outer side of the push plate 9, the supporting sleeve 16 is provided with a sliding rod 17, one end of the sliding rod 17 passes through the supporting sleeve 16 and slides relatively, the sliding rod 17 and the supporting sleeve 16 are elastically connected through a third plate spring 18, the sliding rod 17 is perpendicular to the second auxiliary plate 8, the other end of the sliding rod 17 is obliquely hinged with an arc-shaped plate 19, the outer end of the arc-shaped plate 19 is obliquely hinged with a buckle plate 20, and the end part of the buckle plate 20 is hinged on the outer end surface of the push plate 9.

Specifically, the buckle 20 inclines outwards on the push plate 9 in the initial state, at this moment, the buckle 20 can serve as a guide to conduct guiding treatment on the plate, the plate can conveniently enter between the second auxiliary plate 8 and the push plate 9 smoothly, when the push plate 9 slides relatively on the second auxiliary plate 8, the push plate 9 can pull the buckle 20 to move, at this moment, the slide rod 17 and the arc plate 19 provide supporting and guiding force for the buckle 20, the buckle 20 rotates to the position between the second auxiliary plate 8 and the push plate 9 from the outwards inclined state, the buckle 20 seals the top of the plate, and therefore clamping fixing treatment is conducted on the plate in multiple directions.

When the height of the plate on the second auxiliary plate 8 is smaller, the buckle plate 20 is obliquely and lapped on the top of the plate, the push plate 9 in a continuously moving state can push the slide rod 17 to slide downwards on the support sleeve 16 through the buckle plate 20 and the arc plate 19, and the third plate spring 18 is elastically deformed, so that enough movable space is provided for the buckle plate 20, and the action range of the buckle plate 20 is enlarged.

Preferably, as shown in fig. 3, a plurality of rows of shielding plates 21 are annularly arranged on the outer wall of the rotary drum 1, each row of shielding plates 21 is along the axial direction of the rotary drum 1, each row of shielding plates 21 is composed of a plurality of shielding plates 21, and the surface of each shielding plate 21 faces the push plate 9 downwards;

the outer wall of the rotary drum 1 between two adjacent shielding plates 21 in each row of shielding plates 21 is provided with a process port 22.

Specifically, the outer end of the shielding plate 21 extends outwards, the plate is clamped between the shielding plate 21 and the push plate 9, after the plate is cut, the plate can slide outwards along the shielding plate 21, so that the plate is guided to be processed through the shielding plate 21, the plate is prevented from sliding onto the adjacent sliding rods 17 and being clamped on the adjacent sliding rods 17, the shielding plate 21 shields the adjacent sliding rods 17, a process opening 22 is formed, space is provided for cutting work of the cutting blade 6 conveniently, and damage to the outer wall of the rotary drum 1 caused by the cutting blade 6 is avoided.

Preferably, as shown in fig. 7, the cutting part further includes two opposite base plates 23, a swinging disc 24 is rotatably arranged at the bottom of the base plates 23, a square column 25 is fixed between the two swinging discs 24, a plurality of extension arms 26 are arranged on the square column 25, and the cutting blade 6 is rotatably mounted on the extension arms 26;

one of them is fixed with fixed plate 27 on the base plate 23, is fixed with first motor 28 on the fixed plate 27, and the output of first motor 28 is equipped with connecting rod 29, and the outer end of connecting rod 29 is equipped with pushes away post 30, pushes away post 30 and the output of first motor 28 eccentric, has seted up the spout along its radial direction on the lateral wall of wobble plate 24, pushes away the outer end slidable mounting of post 30 in the spout.

Specifically, the first motor 28 drives the pushing post 30 to eccentrically rotate through the connecting rod 29, the pushing post 30 drives the swinging disc 24 to reciprocally swing through the sliding groove, and the swinging disc 24 drives the square post 25, the extension arm 26 and the cutting blade 6 to reciprocally swing, so that the cutting blade 6 is close to the plate to cut the plate or far away from the rotary drum 1 to enable the rotary drum 1 to normally convey the plate.

Preferably, as shown in fig. 7, the cutter also comprises a second motor 31, the second motor 31 is mounted on one swinging disc 24, a first worm 32 is arranged at the output end of the second motor 31, the first worm 32 is rotatably mounted between the two swinging discs 24, the first worm 32 penetrates through the extension arm 26 and slides relatively, a plurality of first worm gears 33 are meshed on the first worm 32, a second worm 34 is arranged on the first worm gears 33 in a transmission manner, the second worm 34 is rotatably mounted on the extension arm 26, a second worm gear 35 is arranged at the outer end of the second worm 34, and the second worm gear 35 is in transmission connection with the cutting blade 6.

Specifically, the second motor 31 may drive the first worm 32 to rotate, and the first worm 32 may drive the plurality of cutting blades 6 to synchronously rotate through the first worm wheel 33, the second worm 34 and the second worm wheel 35, so as to provide power for the cutting blades 6 at any position.

Preferably, as shown in fig. 8, the device further comprises a translation plate 36, the translation plate 36 is positioned at the bottom of the extension arm 26, the end part of the translation plate 36 is slidably mounted on the side wall of the swinging disc 24, the sliding direction of the translation plate 36 is parallel to the length direction of the extension arm 26, a plurality of guide grooves are formed in the translation plate 36, the guide grooves incline, an adjusting column 37 is slidably arranged in the guide grooves, the adjusting column 37 is fixed on the extension arm 26, an air cylinder 38 is fixed on the swinging disc 24, and the output end of the air cylinder 38 is connected with the translation plate 36;

wherein, the extension arm 26 slides on the square column 25, and the translation plate 36 can push the plurality of adjusting columns 37 to synchronously move through a plurality of guide grooves in an inclined state when moving, and the distance between two adjacent adjusting columns 37 is always kept equal, thereby realizing the purpose of equidistant movement of the plurality of adjusting columns 37.

Specifically, extension lines of the plurality of adjusting columns 37 intersect at a point, and the translation plate 36 can be pushed to move through the air cylinder 38, so that the plurality of adjusting columns 37 are driven to synchronously and equidistantly move, at the moment, the plurality of extension arms 26 synchronously and equidistantly move, so that the positions of the plurality of cutting pieces 6 are adjusted, the distances among the plurality of cutting pieces 6 are always kept equal, and the widths of the plurality of cut plates are synchronously adjusted.

Preferably, as shown in fig. 2, a third motor 39 is fixed on the outer wall of the support shaft 2, a driving wheel 40 is driven at the output end of the third motor 39, a driving ring 41 is arranged on the end face of the rotary drum 1, and the driving wheel 40 is in driving connection with the driving ring 41.

Specifically, the third motor 39 drives the drum 1 to rotate through the driving wheel 40 and the driving ring 41.

The foregoing is merely a preferred embodiment of the present invention, and it should be noted that it will be apparent to those skilled in the art that modifications and variations can be made without departing from the technical principles of the present invention, and these modifications and variations should also be regarded as the scope of the invention.

Claims (9)

1. The plate cutting device for producing the multilayer solid wood composite floor is characterized by comprising a cutting part positioned at the upper side and a conveying part positioned at the lower side, wherein the conveying part comprises a rotary drum (1) and a supporting shaft (2), the axis of the supporting shaft (2) is horizontal, the rotary drum (1) is rotatably arranged on the supporting shaft (2) and supports the rotary drum (1) through the supporting shaft (2), a plurality of groups of annular groove plates (3) are sequentially arranged on the outer wall of the supporting shaft (2) at the inner side of the rotary drum (1) along the axis direction of the supporting shaft (2), each group of annular groove plates (3) consists of two annular groove plates (3), the annular groove plates (3) are sleeved and fixed on the outer wall of the supporting shaft (2), the directions of the two annular groove plates (3) are opposite, the top of the annular groove plates (3) are horizontal, a plurality of slide columns (4) are arranged in a sliding manner in each group of annular groove plates (3), the slide columns (4), the outer ends of the right-angle clamping plates (5) penetrate through the rotary drum (1) and slide to the right-angle clamping plates (5) at the outer sides of the right-angle clamping plates (1) of the rotary drum (1);

the cutting part consists of a plurality of equally spaced cutting pieces (6).

2. The board cutting device for producing the multi-layer solid wood composite floor according to claim 1, wherein the right angle clamping board (5) is composed of a first auxiliary board (7), a second auxiliary board (8) and a pushing board (9), the first auxiliary board (7) is fixedly connected with the sliding column (4), the second auxiliary board (8) is slidingly connected with the first auxiliary board (7), the second auxiliary board (8) is elastically connected with the first auxiliary board (7) through a first plate spring (10), the second auxiliary board (8) penetrates through the rotary drum (1) and slides relatively, and the pushing board (9) is arranged on the end part of the second auxiliary board (8) outside the rotary drum (1).

3. The plate cutting device for producing the multi-layer solid wood composite floor according to claim 2, wherein one surface of the push plate (9) facing the outer wall of the rotary drum (1) is sequentially provided with a clamping surface (11), an inclined surface (12) and a limiting surface (13) from top to bottom, the clamping surface (11) and the limiting surface (13) are perpendicular to the second auxiliary plate (8), the outer end of the second auxiliary plate (8) is inclined and slidably arranged on the inclined surface (12), and the push plate (9) is elastically connected with the second auxiliary plate (8) through a second plate spring (14).

4. A board cutting device for producing a multilayer solid wood composite floor according to claim 3, characterized in that a notch (15) is formed in the middle of the push plate (9), a supporting sleeve (16) is arranged on the end face of a second auxiliary plate (8) on the inner side of the notch (15), the supporting sleeve (16) extends to the outer side of the push plate (9), a sliding rod (17) is arranged on the supporting sleeve (16), one end of the sliding rod (17) penetrates through the supporting sleeve (16) and slides relatively, the sliding rod (17) is elastically connected with the supporting sleeve (16) through a third plate spring (18), the sliding rod (17) is perpendicular to the second auxiliary plate (8), an arc plate (19) is obliquely hinged to the other end of the sliding rod (17), a buckle plate (20) is obliquely hinged to the outer end of the arc plate (19), and the end of the buckle plate (20) is hinged to the outer end face of the push plate (9).

5. The board cutting device for producing the multi-layer solid wood composite floor according to claim 4, wherein a plurality of rows of shielding plates (21) are annularly arranged on the outer wall of the rotary drum (1), each row of shielding plates (21) is along the axis direction of the rotary drum (1), each row of shielding plates (21) is composed of a plurality of shielding plates (21), and the surface of each shielding plate (21) faces to the push plate (9);

the outer wall of the rotary drum (1) between two adjacent shielding plates (21) in each row of shielding plates (21) is provided with a process port (22).

6. The plate cutting device for producing the multi-layer solid wood composite floor according to claim 5, wherein the cutting part further comprises two oppositely arranged base plates (23), the bottom of the base plates (23) is rotatably provided with swinging discs (24), square columns (25) are fixed between the two swinging discs (24), a plurality of extension arms (26) are arranged on the square columns (25), and the cutting piece (6) is rotatably arranged on the extension arms (26);

one of them is fixed with fixed plate (27) on base plate (23), is fixed with first motor (28) on fixed plate (27), and the output of first motor (28) is equipped with connecting rod (29), and the outer end of connecting rod (29) is equipped with pushes away post (30), pushes away post (30) and the output of first motor (28) eccentric, has seted up the spout along its radial direction on the lateral wall of wobble plate (24), pushes away the outer end slidable mounting of post (30) in the spout.

7. The board cutting device for producing the multi-layer solid wood composite floor according to claim 6, further comprising a second motor (31), wherein the second motor (31) is installed on one swinging disc (24), the output end of the second motor (31) is provided with a first worm (32), the first worm (32) is rotatably installed between the two swinging discs (24), the first worm (32) penetrates through the extension arm (26) and slides relatively, a plurality of first worm gears (33) are meshed on the first worm (32), a second worm (34) is arranged on the first worm gear (33) in a transmission mode, the second worm (34) is rotatably installed on the extension arm (26), the outer end of the second worm (34) is provided with a second worm gear (35), and the second worm gear (35) is in transmission connection with the cutting piece (6).

8. The board cutting device for producing the multi-layer solid wood composite floor according to claim 7, further comprising a translation plate (36), wherein the translation plate (36) is positioned at the bottom of the extension arm (26), the end part of the translation plate (36) is slidably mounted on the side wall of the swinging plate (24), the sliding direction of the translation plate (36) is parallel to the length direction of the extension arm (26), a plurality of guide grooves are formed in the translation plate (36), the guide grooves are inclined, an adjusting column (37) is slidably arranged in the guide grooves, the adjusting column (37) is fixed on the extension arm (26), an air cylinder (38) is fixed on the swinging plate (24), and the output end of the air cylinder (38) is connected with the translation plate (36);

the extension arm (26) slides on the square column (25), the translation plate (36) can push the plurality of adjusting columns (37) to synchronously move through a plurality of guide grooves in an inclined state when moving, and the distance between two adjacent adjusting columns (37) is always kept equal, so that the aim of equidistant movement of the plurality of adjusting columns (37) is fulfilled.

9. The plate cutting device for producing the multi-layer solid wood composite floor according to claim 8, wherein a third motor (39) is fixed on the outer wall of the supporting shaft (2), a driving wheel (40) is driven at the output end of the third motor (39), a driving ring (41) is arranged on the end face of the rotary drum (1), and the driving wheel (40) is in driving connection with the driving ring (41).