CN111702914A - Multi-functional wood working equipment for building - Google Patents

Abstract

The invention relates to wood processing equipment, in particular to multifunctional wood processing equipment for buildings, which comprises a transverse crushing mechanism, a longitudinal crushing mechanism, a stirring mechanism and a pressing mechanism, wherein the equipment can crush wood into boards, the equipment can crush the wood into small blocks, the equipment can stir the small blocks with an adhesive, the equipment can press the mixture of the stirred wood and the adhesive into a synthetic board, the crushing mechanism is connected with the longitudinal crushing mechanism, the longitudinal crushing mechanism is connected with the stirring mechanism, the stirring mechanism is connected with the transverse crushing mechanism, the pressing mechanism is connected with the transverse crushing mechanism, and the stirring mechanism is connected with the pressing mechanism.

Description

Multi-functional wood working equipment for building

Technical Field

The invention relates to sampling equipment, in particular to multifunctional wood processing equipment for buildings.

Background

When the composite board for the building is processed, a plurality of process types are frequently generated and are complicated, but no better equipment for processing the wood composite board exists in the market, so the multifunctional wood processing equipment for the building is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing the multifunctional wood processing equipment for the building, the equipment can crush wood into boards, the equipment can crush the wood into boards into small pieces, the equipment can stir the small pieces of the wood and the adhesive, and the equipment can press the mixture of the stirred wood and the adhesive into the synthetic board.

In order to solve the technical problems, the invention relates to wood processing equipment, in particular to multifunctional wood processing equipment for buildings, which comprises a transverse crushing mechanism, a longitudinal crushing mechanism, a stirring mechanism and a pressing mechanism, wherein the equipment can crush wood into boards, the equipment can crush the wood into small pieces, the equipment can stir the small pieces of the wood with a bonding agent, and the equipment can press the mixture of the stirred wood and the bonding agent into a synthetic board.

The transverse crushing mechanism is connected with the longitudinal crushing mechanism, the longitudinal crushing mechanism is connected with the stirring mechanism, the stirring mechanism is connected with the transverse crushing mechanism, the pressing mechanism is connected with the transverse crushing mechanism, and the stirring mechanism is connected with the pressing mechanism.

As a further optimization of the technical scheme, the invention relates to a multifunctional wood processing device for buildings, wherein the transverse crushing mechanism comprises a transverse motor, a transverse motor shaft, a transverse belt a, a transverse transmission shaft a, a rotary column, a crushing cutter, a transverse belt b, a transverse transmission shaft b, a transverse transmission gear a, a transverse transmission gear b, a transverse transmission shaft c, a feeding inclined plate, a connecting plate a, a connecting side plate, a connecting plate b, a connecting plate c, a connecting plate d, a connecting plate e, a connecting plate f, a connecting plate g and an output block, wherein the transverse motor is connected with the transverse motor shaft, the transverse motor shaft is in friction connection with the transverse belt a, the transverse belt a is in friction connection with the transverse transmission shaft a, the transverse transmission shaft a is connected with the rotary column, the rotary column is connected with the crushing cutter, the transverse belt b is in friction connection with the transverse transmission shaft, the transverse transmission gear a is connected with a transverse transmission shaft b, the transverse transmission gear b is meshed with the transverse transmission gear a, the transverse transmission shaft c is connected with the transverse transmission gear b, the feeding inclined plate is connected with a connecting plate a, the connecting plate a is connected with a connecting side plate, the connecting side plate is connected with the connecting plate b, the connecting plate b is connected with a connecting plate c, the connecting plate c is connected with a connecting plate d, the connecting plate d is connected with a connecting side plate, a connecting plate e is connected with a connecting side plate, a connecting plate f is connected with a connecting side plate, a connecting plate g is connected with a connecting side plate, the output block is connected with the connecting plate a, the connecting plate a is connected with a connecting plate g, the connecting side plate is connected with a transverse motor, the connecting side plate is connected with a transverse transmission shaft a bearing, the connecting side plate is connected with a, the connecting plate b is connected with the connecting plate f, the connecting plate b is connected with the output block, the connecting plate c is connected with the connecting plate d, the connecting plate c is connected with the connecting plate e, the connecting plate d is connected with the connecting plate f, and the connecting plate g is connected with the connecting plate a.

As a further optimization of the technical scheme, the invention relates to a multifunctional wood processing device for buildings, wherein the longitudinal crushing mechanism comprises a longitudinal motor, a longitudinal motor shaft, a longitudinal belt, a longitudinal transmission shaft, a longitudinal transmission column, a longitudinal thread crushing cutter, a longitudinal crushing groove, a longitudinal connecting plate and a longitudinal output block, the longitudinal motor is connected with the longitudinal motor shaft, the longitudinal motor shaft is in friction connection with the longitudinal belt, the longitudinal belt is in friction connection with the longitudinal transmission shaft, the longitudinal transmission shaft is connected with the longitudinal transmission column, the longitudinal transmission column is connected with the longitudinal thread crushing cutter, the longitudinal thread crushing cutter is in sliding connection with the longitudinal crushing groove, the longitudinal crushing groove is connected with the longitudinal connecting plate, the longitudinal connecting plate is connected with a connecting side plate, the longitudinal output block is connected with a connecting side plate, the longitudinal motor is connected with a connecting plate b, the longitudinal transmission shaft is connected with a bearing of the connecting, the longitudinal crushing groove is connected with a connecting plate b, the longitudinal connecting plate is connected with a connecting side plate, the longitudinal connecting plate is connected with the connecting plate b, and the longitudinal output block is connected with the connecting plate b.

As a further optimization of the technical scheme, the invention relates to a multifunctional wood processing device for buildings, wherein the stirring mechanism comprises a stirring belt a, a stirring transmission shaft a, a stirring belt b, a stirring transmission shaft b, a stirring friction wheel, a stirring transmission shaft c, a stirring bearing plate, a stirring barrel, a feeding pipe, a stirring barrel sliding door mechanism, a stirring output inclined plate and a stirring barrel bottom plate, the stirring belt a is in friction connection with the stirring transmission shaft a, the stirring transmission shaft a is in friction connection with the stirring belt b, the stirring belt b is in friction connection with the stirring transmission shaft b, the stirring transmission shaft b is in bearing connection with a connecting plate a, the stirring friction wheel is in friction connection with the stirring belt b, the stirring transmission shaft c is connected with the stirring transmission shaft c, the stirring plate is connected with the stirring transmission shaft c, and the stirring barrel is in sliding connection with the stirring plate, the stirring device comprises a feeding pipe, a stirring barrel, a stirring output inclined plate, a connecting plate b, a stirring belt a, a longitudinal transmission shaft, a stirring transmission shaft a, a connecting plate a bearing, a stirring transmission shaft a, a connecting plate b bearing, a connecting side plate and a stirring barrel, wherein the feeding pipe is connected with the stirring barrel; the agitator sliding door mechanism includes the handle, the sliding door connecting plate, the stopper, spacing axle, the limiting plate, spacing spring, go up the stopper, the slip stopper, the handle is connected with the sliding door, the sliding door is connected with the sliding door connecting plate, the sliding door connecting plate and stopper sliding connection, the stopper is connected with spacing hub connection, spacing axle and limiting plate sliding connection, the limiting plate is connected with the agitator, spacing spring housing is spacing epaxial and spacing in stopper and limiting plate, go up stopper and limiting plate connection, slip stopper and sliding door sliding connection, sliding door and agitator sliding connection.

As a further optimization of the technical scheme, the invention relates to a multifunctional wood processing device for buildings, wherein the pressing mechanism comprises a pressing belt, a pressing transmission shaft, a pressing rotary column, a transmission belt connecting soft plate, a pressing connecting plate, a sliding inclined plate, an inclined plate connecting plate a, an inclined plate connecting plate b, an inclined plate sliding column, a pressing sliding plate, a pressing reset spring, a pressing glue discharging hole, a pressing glue discharging pipe and a pressing discharging inclined plate, the pressing belt is in friction connection with the pressing transmission shaft, the pressing transmission shaft is connected with the pressing rotary column, the pressing rotary column is in friction connection with the transmission belt, the transmission belt is connected with the transmission belt connecting soft plate, the transmission belt connecting soft plate is connected with the pressing connecting plate, the pressing connecting plate is connected with the transmission belt, the sliding inclined plate is connected with the inclined plate connecting plate a, the inclined plate connecting, the inclined plate sliding column is connected with an inclined plate connecting plate a, the pressing sliding plate is connected with the inclined plate sliding column in a sliding mode, the pressing reset spring is sleeved on the inclined plate sliding column and is limited to the inclined plate connecting plate a and the pressing sliding plate, a pressing glue discharging hole is formed in a conveying belt connecting soft plate, a pressing glue discharging pipe is connected with the conveying belt in a sliding mode, the pressing discharging inclined plate is connected with a connecting side plate, a pressing belt is in friction connection with a transverse transmission shaft c, the pressing transmission shaft is connected with the connecting side plate, the conveying belt is connected with the soft plate and is connected with the connecting side plate in a sliding mode, the pressing connecting plate is connected with the sliding inclined plate in a sliding mode, the pressing sliding plate is connected with.

As a further optimization of the technical scheme, any point on each longitudinal thread crushing cutter is connected clockwise to form a thread line.

The multifunctional wood processing equipment for the building has the beneficial effects that:

the multifunctional wood processing equipment for the building can crush wood into boards, the wood crushed into boards by the equipment can be crushed into small pieces, the small pieces of the wood can be stirred with the adhesive by the equipment, and the mixture of the stirred wood and the adhesive can be pressed into the synthetic board by the equipment.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a first structural schematic diagram of a multifunctional wood processing device for buildings according to the invention.

Fig. 2 is a schematic structural diagram of a multifunctional wood processing device for building of the present invention.

Fig. 3 is a first structural schematic diagram of the transverse crushing mechanism 1 of the multifunctional wood processing equipment for buildings according to the invention.

Fig. 4 is a second structural schematic diagram of the transverse crushing mechanism 1 of the multifunctional wood processing equipment for building of the invention.

Fig. 5 is a third schematic structural diagram of the transverse crushing mechanism 1 of the multifunctional wood processing equipment for buildings according to the invention.

Fig. 6 is a schematic structural view of the output blocks 1-21 of the multifunctional wood processing equipment for construction according to the present invention.

Fig. 7 is a schematic structural view of a longitudinal crushing mechanism 2 of the multifunctional wood working equipment for construction of the present invention.

Fig. 8 is a first structural schematic diagram of the stirring mechanism 3 of the multifunctional wood processing equipment for construction.

Fig. 9 is a second structural schematic diagram of the stirring mechanism 3 of the multifunctional wood processing equipment for construction of the invention.

Fig. 10 is a third schematic structural diagram of the stirring mechanism 3 of the multifunctional wood processing equipment for construction according to the invention.

Fig. 11 is a schematic structural view of a sliding door mechanism 3-11 of a mixing tank of the multifunctional wood processing equipment for construction.

Fig. 12 is a schematic structural view of a limiting shaft 3-11-5 of the multifunctional wood processing equipment for construction of the present invention.

Fig. 13 is a first structural schematic diagram of the pressing mechanism 4 of the multifunctional wood processing equipment for building of the invention.

Fig. 14 is a second structural schematic diagram of the pressing mechanism 4 of the multifunctional wood processing equipment for construction of the invention.

Fig. 15 is a third schematic structural diagram of the pressing mechanism 4 of the multifunctional wood processing equipment for construction according to the invention.

In the figure: a transverse crushing mechanism 1; a transverse motor 1-1; a transverse motor shaft 1-2; transverse belt a 1-3; a transverse transmission shaft a 1-4; 1-5 of a rotating column; 1-6 parts of a crushing knife; transverse belt b 1-7; a transverse transmission shaft b 1-8; cross-drive gear a 1-9; a cross drive gear b 1-10; a transverse transmission shaft c 1-11; feed inclined plates 1 to 12; connection board a 1-13; connecting the side plates 1-14; connecting plate b 1-15; connecting plate c 1-16; connecting plate d 1-17; connecting plate e 1-18; connecting plates f 1-19; connecting plates g 1-20; output blocks 1-21; a longitudinal crushing mechanism 2; a longitudinal motor 2-1; a longitudinal motor shaft 2-2; 2-3 of a longitudinal belt; 2-4 of a longitudinal transmission shaft; 2-5 of a longitudinal transmission column; 2-6 of a longitudinal thread crushing cutter; 2-7 of longitudinal crushing grooves; 2-8 of longitudinal connecting plates; longitudinal output blocks 2-9; a stirring mechanism 3; stirring belt a 3-1; a stirring transmission shaft a 3-2; a stirring belt b 3-3; a stirring transmission shaft b 3-4; 3-5 parts of a stirring friction wheel; a stirring transmission shaft c 3-6; 3-7 parts of a stirring bearing plate; 3-8 parts of a stirring plate; 3-9 parts of a stirring barrel; 3-10 parts of a feeding pipe; a mixing tank sliding door mechanism 3-11; 3-11-1 of a handle; a sliding door 3-11-2; a sliding door connecting plate 3-11-3; 3-11-4 parts of a limiting block; 3-11-5 parts of a limiting shaft; 3-11-6 parts of a limiting plate; 3-11-7 parts of a limiting spring; 3-11-8 of an upper limiting block; 3-11-9 parts of a sliding limiting block; 3-12 parts of a stirring output inclined plate; 3-13 parts of a bottom plate of the stirring barrel; a pressing mechanism 4; pressing a belt 4-1; pressing a transmission shaft 4-2; pressing the rotating column 4-3; 4-4 of a conveyor belt; the conveying belt is connected with the soft board 4-5; pressing the connecting plates 4-6; sliding inclined plates 4-7; an inclined plate connecting plate a 4-8; an inclined plate connecting plate b 4-9; 4-10 parts of sloping plate sliding column; pressing the sliding plate 4-11; pressing a return spring 4-12; pressing glue discharging holes 4-13; pressing a rubber discharge pipe 4-14; pressing the discharge sloping plate 4-15.

Detailed Description

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and fig. 15, and the present invention relates to a wood processing apparatus, and more specifically, to a multifunctional wood processing apparatus for construction, which includes a transverse crushing mechanism 1, a longitudinal crushing mechanism 2, a stirring mechanism 3, and a pressing mechanism 4, and is capable of crushing wood into boards, and crushing the wood of the boards into small pieces, stirring the small pieces of wood with a binder, and pressing the mixture of the stirred wood and the binder into a composite board.

Horizontal crushing mechanism 1 is connected with vertical crushing mechanism 2, and vertical crushing mechanism 2 is connected with rabbling mechanism 3, and rabbling mechanism 3 is connected with horizontal crushing mechanism 1, and pressing means 4 is connected with horizontal crushing mechanism 1, and rabbling mechanism 3 is connected with pressing means 4.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and fig. 15, and the present embodiment further describes the present embodiment, where the lateral crushing mechanism 1 includes a lateral motor 1-1, a lateral motor shaft 1-2, a lateral belt a1-3, a lateral transmission shaft a1-4, a rotary column 1-5, a crushing knife 1-6, a lateral belt b1-7, a lateral transmission shaft b1-8, a lateral transmission gear a1-9, a lateral transmission gear b1-10, a lateral transmission shaft c1-11, a feed inclined plate 1-12, a connecting plate a1-13, a connecting side plate 1-14, a connecting plate b1-15, a connecting plate c1-16, a connecting plate d1-17, a connecting plate c 85, A connecting plate e1-18, a connecting plate f1-19, a connecting plate g1-20 and an output block 1-21, wherein a transverse motor 1-1 is connected with a transverse motor shaft 1-2, a transverse motor shaft 1-2 is in frictional connection with a transverse belt a1-3, a transverse belt a1-3 is in frictional connection with a transverse transmission shaft a1-4, a transverse transmission shaft a1-4 is connected with a rotary column 1-5, a rotary column 1-5 is connected with a crushing knife 1-6, a transverse belt b1-7 is in frictional connection with a transverse transmission shaft a1-4, a transverse transmission shaft b1-8 is in frictional connection with a transverse belt b1-7, a transverse transmission gear a1-9 is connected with a transverse transmission shaft b1-8, a transverse transmission gear b1-10 is meshed with a transverse transmission gear a1-9, a transverse transmission shaft c1-11 is connected with a transverse transmission gear b1-, the feeding inclined plates 1-12 are connected with connecting plates a1-13, the connecting plates a1-13 are connected with connecting side plates 1-14, the connecting side plates 1-14 are connected with connecting plates b1-15, the connecting plates b1-15 are connected with connecting plates c1-16, the connecting plates c1-16 are connected with connecting plates d1-17, the connecting plates d1-17 are connected with connecting side plates 1-14, the connecting plates e1-18 are connected with connecting side plates 1-14, the connecting plates f1-19 are connected with connecting side plates 1-14, the connecting plates g1-20 are connected with connecting side plates 1-14, the output blocks 1-21 are connected with connecting plates 1-13, the connecting plates a1-13 are connected with connecting plates g1-20, the connecting side plates 1-14 are connected with transverse motors 1-1, the connecting side plates 1-14 are connected with transverse transmission shaft a1-4 bearings, connecting side plates 1-14 are in bearing connection with a transverse transmission shaft b1-8, connecting side plates 1-14 are connected with a transverse transmission shaft c1-11, connecting side plates 1-14 are connected with a feeding inclined plate 1-12, connecting side plates 1-14 are connected with a connecting plate c1-16, connecting plates b1-15 are connected with a connecting plate f1-19, connecting plates b1-15 are connected with output blocks 1-21, connecting plates c1-16 are connected with connecting plates d1-17, connecting plates c1-16 are connected with connecting plates e1-18, connecting plates d1-17 are connected with connecting plates f1-19, connecting plates g1-20 are connected with connecting plates a1-13, the device can crush wood into plates, place the wood on the feeding inclined plates 1-12, the wood inclines downwards through the feeding inclined plates 1-12, the transverse motor 1-1 works, the transverse motor 1-1 works to drive the transverse motor shaft 1-2 to rotate, the transverse motor shaft 1-2 rotates to drive the transverse transmission shaft a1-4 to rotate through a transverse belt a1-3, the transverse transmission shaft a1-4 rotates to drive the transverse transmission shaft c1-11 to rotate through a transverse belt b1-7, the transverse transmission shaft a1-4 and the transverse transmission shaft c1-11 rotate to drive the two rotary columns 1-5 to rotate in a forward direction and a reverse direction simultaneously, the rotary columns 1-5 rotate to drive the crushing cutters 1-6 to rotate, wood is crushed into boards when the crushing cutters 1-6 rotate, and the crushed boards are downwards inclined through the output blocks 1-21.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and fig. 15, and the embodiment further describes the embodiment, where the longitudinal crushing mechanism 2 includes a longitudinal motor 2-1, a longitudinal motor shaft 2-2, a longitudinal belt 2-3, a longitudinal transmission shaft 2-4, a longitudinal transmission column 2-5, a longitudinal thread crushing knife 2-6, a longitudinal crushing slot 2-7, a longitudinal connecting plate 2-8, a longitudinal output block 2-9, the longitudinal motor 2-1 is connected with the longitudinal motor shaft 2-2, the longitudinal motor shaft 2-2 is frictionally connected with the longitudinal belt 2-3, the longitudinal belt 2-3 is frictionally connected with the longitudinal transmission shaft 2-4, a longitudinal transmission shaft 2-4 is connected with a longitudinal transmission column 2-5, the longitudinal transmission column 2-5 is connected with a longitudinal thread crushing cutter 2-6, the longitudinal thread crushing cutter 2-6 is connected with a longitudinal crushing groove 2-7 in a sliding manner, the longitudinal crushing groove 2-7 is connected with a longitudinal connecting plate 2-8, the longitudinal connecting plate 2-8 is connected with a connecting side plate 1-14, a longitudinal output block 2-9 is connected with a connecting side plate 1-14, a longitudinal motor 2-1 is connected with a connecting plate b1-15, the longitudinal transmission shaft 2-4 is connected with a connecting plate a1-13 bearing, the longitudinal transmission shaft 2-4 is connected with a connecting plate b1-15 bearing, the longitudinal crushing groove 2-7 is connected with a connecting plate b1-15, the longitudinal connecting plate 2-8 is connected with a connecting side plate 1-14, the longitudinal connecting plates 2-8 are connected with the connecting plates b1-15, the longitudinal output blocks 2-9 are connected with the connecting plates b1-15, the wood which can be crushed into boards by the equipment is crushed into small blocks, the crushed boards which are inclined downwards through the output blocks 1-21 are inclined into the longitudinal crushing grooves 2-7 through the longitudinal connecting plates 2-8, at the moment, the longitudinal motor 2-1 works to drive the longitudinal motor shaft 2-2 to rotate, the longitudinal motor shaft 2-2 rotates to drive the longitudinal transmission shaft 2-4 to rotate through the longitudinal belt 2-3, the longitudinal transmission shaft 2-4 rotates to drive the longitudinal transmission column 2-5 to rotate, the longitudinal transmission column 2-5 rotates to drive the longitudinal thread crushing cutter 2-6 to rotate, the longitudinal thread crushing cutter 2-6 rotates to crush the wood crushed into small blocks, and the wood small blocks are conveyed to the direction of a longitudinal motor 2-1 under the action of a longitudinal thread crushing knife 2-6, and when the wood small blocks are conveyed to a gap between a longitudinal crushing groove 2-7 and a connecting plate b1-15, the wood small blocks fall downwards and are downwards inclined under the action of a longitudinal output block 2-9.

The fourth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and fig. 15, and the present embodiment further describes the present embodiment, where the stirring mechanism 3 includes a stirring belt a3-1, a stirring transmission shaft a3-2, a stirring belt b3-3, a stirring transmission shaft b3-4, a stirring friction wheel 3-5, a stirring transmission shaft c3-6, a stirring shaft carrier plate 3-7, a stirring plate 3-8, a stirring barrel 3-9, a feeding pipe 3-10, a stirring barrel sliding door mechanism 3-11, a stirring output inclined plate 3-12, and a stirring barrel bottom plate 3-13, the stirring belt a3-1 is frictionally connected to the stirring transmission shaft a3-2, the stirring transmission shaft a3-2 is frictionally connected to the stirring belt b3-3, the stirring belt b3-3 is in friction connection with a stirring transmission shaft b3-4, the stirring transmission shaft b3-4 is in bearing connection with a connecting plate a1-13, the stirring friction wheel 3-5 is in friction connection with the stirring belt b3-3, the stirring transmission shaft c3-6 is in connection with the stirring friction wheel 3-5, the stirring shaft bearing plate 3-7 is in bearing connection with a stirring transmission shaft c3-6, the stirring plate 3-8 is in connection with the stirring transmission shaft c3-6, the stirring barrel 3-9 is in sliding connection with the stirring plate 3-8, the feeding pipe 3-10 is in connection with the stirring barrel 3-9, the stirring barrel sliding door mechanism 3-11 is in connection with the stirring barrel 3-9, the stirring output inclined plate 3-12 is in connection with a connecting plate b1-15, a connecting plate a1-13 is in connection with the stirring barrel 3-9, the stirring belt a3-1 is in friction, the stirring transmission shaft a3-2 is connected with a connecting plate a1-13 bearing, the stirring transmission shaft a3-2 is connected with a connecting plate b1-15 bearing, the stirring transmission shaft b3-4 is connected with a connecting plate b1-15 bearing, and the stirring barrel 3-9 is connected with a connecting side plate 1-14; the stirring barrel sliding door mechanism 3-11 comprises a handle 3-11-1, a sliding door 3-11-2, a sliding door connecting plate 3-11-3, a limiting block 3-11-4, a limiting shaft 3-11-5, a limiting plate 3-11-6, a limiting spring 3-11-7, an upper limiting block 3-11-8 and a sliding limiting block 3-11-9, wherein the handle 3-11-1 is connected with the sliding door 3-11-2, the sliding door 3-11-2 is connected with the sliding door connecting plate 3-11-3, the sliding door connecting plate 3-11-3 is connected with the limiting block 3-11-4 in a sliding manner, the limiting block 3-11-4 is connected with the limiting shaft 3-11-5, the limiting shaft 3-11-5 is connected with the limiting plate 3-11-6 in a sliding mode, the limiting plate 3-11-6 is connected with the stirring barrel 3-9, the limiting spring 3-11-7 is sleeved on the limiting shaft 3-11-5 and limited on the limiting plate 3-11-4 and the limiting plate 3-11-6, the upper limiting block 3-11-8 is connected with the limiting plate 3-11-6, the sliding limiting block 3-11-9 is connected with the sliding door 3-11-2 in a sliding mode, the sliding door 3-11-2 is connected with the stirring barrel 3-9 in a sliding mode, the wood small blocks can be stirred by the equipment with the adhesive, the small blocks which are inclined down through the longitudinal output block 2-9 fall into the stirring barrel 3-9, the adhesive is injected into the stirring barrel 3-9 through the feeding pipe 3-10, at the moment, a longitudinal motor 2-1 rotates to drive a stirring transmission shaft a3-2 to rotate through a stirring belt a3-1, the stirring transmission shaft a3-2 rotates to drive a stirring transmission shaft b3-4 to rotate through a stirring belt b3-3, the stirring belt b3-3 also drives a stirring friction wheel 3-5 to rotate when in motion, the stirring friction wheel 3-5 rotates to drive a stirring transmission shaft c3-6 to rotate, the stirring transmission shaft c3-6 rotates to drive a stirring plate 3-8 to rotate, the stirring plate 3-8 rotates to uniformly stir wood small blocks and adhesives in a space formed by a stirring barrel 3-9 and a stirring barrel bottom plate 3-13, a handle 3-11-1 is pulled, a handle 3-11-1 moves to drive a sliding door 3-11-2 and a sliding door connecting plate 3-11-3, the sliding door connecting plate 3-11-3 moves to press the limiting blocks 3-11-4 to move towards the limiting plates 3-11-6, when the sliding door connecting plate 3-11-3 moves to a position between the upper limiting block 3-11-4 and the upper limiting block 3-11-8, the sliding door 3-11-2 is opened, the limiting blocks 3-11-4 can reset under the action of the limiting springs 3-11-7, and the stirring materials in the space formed by the stirring barrel 3-9 and the stirring barrel bottom plate 3-13 flow out through the opening in the stirring barrel 3-9 after the sliding door 3-11-2 is opened.

The fifth concrete implementation mode:

FIG. 1, FIG. 2, FIG. 3, FIG. 4, FIG. 5, FIG. 6, FIG. 7, FIG. 8, FIG. 9, FIG. 10, FIG. 11, FIG. 12, FIG. 13, FIG. 14, FIG. 15 illustrate the present embodiment, which further illustrates the present embodiment, wherein the pressing mechanism 4 includes a pressing belt 4-1, a pressing transmission shaft 4-2, a pressing rotary column 4-3, a transmission belt 4-4, a transmission belt connecting soft plate 4-5, a pressing connecting plate 4-6, a sliding inclined plate 4-7, an inclined plate connecting plate a4-8, an inclined plate connecting plate b4-9, a sliding column 4-10, a pressing sliding plate 4-11, a pressing return spring 4-12, a pressing rubber discharge hole 4-13, a pressing rubber discharge tube 4-14, a pressing discharge inclined plate 4-15, a pressing belt 4-1 is frictionally connected with the pressing transmission shaft 4-2, a pressing transmission shaft 4-2 is connected with a pressing rotary column 4-3, the pressing rotary column 4-3 is in friction connection with a transmission belt 4-4, the transmission belt 4-4 is connected with a transmission belt connecting soft plate 4-5, the transmission belt connecting soft plate 4-5 is connected with a pressing connecting plate 4-6, the pressing connecting plate 4-6 is connected with the transmission belt 4-4, a sliding inclined plate 4-7 is connected with an inclined plate connecting plate a4-8, an inclined plate connecting plate a4-8 is connected with an inclined plate connecting plate b4-9, an inclined plate connecting plate b4-9 is connected with a sliding inclined plate 4-7, an inclined plate sliding column 4-10 is connected with an inclined plate connecting plate a4-8, a pressing sliding plate 4-11 is in sliding connection with an inclined plate sliding column 4-10, a pressing reset spring 4-12 is sleeved on the inclined plate sliding column 4-10, a limiting and inclined plate connecting plate The pressing glue discharging holes 4-13 are formed in the conveyor belt connecting soft board 4-5, the pressing glue discharging pipes 4-14 are connected with the conveyor belt connecting soft board 4-5 in a sliding mode, the pressing discharging inclined boards 4-15 are connected with the connecting side boards 1-14, the pressing belt 4-1 is in friction connection with the transverse transmission shaft c1-11, the pressing transmission shaft 4-2 is connected with the connecting side boards 1-14, the conveyor belt connecting soft board 4-5 is connected with the connecting side boards 1-14 in a sliding mode, the pressing connecting board 4-6 is connected with the sliding inclined boards 4-7 in a sliding mode, the pressing sliding board 4-11 is connected with the connecting side boards 1-14, the pressing sliding board 4-11 is connected with the stirring output inclined boards 3-12, the pressing glue discharging pipes 4-14 are connected with the connecting side boards 1-14, and the equipment can press the mixture of the stirred, the flowing mixture is downwards inclined to a conveyor belt 4-4 through a stirring output inclined plate 3-12, at the moment, a transverse motor 1-1 rotates clockwise, the transverse motor 1-1 rotates to drive a pressing transmission shaft 4-2 to rotate through a pressing belt 4-1, the pressing transmission shaft 4-2 drives a pressing rotary column 4-3 to rotate, the pressing rotary column 4-3 rotates to drive a pressing rotary column 4-3 at the other side to rotate through the conveyor belt 4-4, the conveyor belt 4-4 has the function of the conveyor belt when the pressing rotary column 4-3 rotates, materials on the conveyor belt 4-4 are conveyed towards the direction of a pressing discharge inclined plate 4-15, the conveyor belt 4-4 simultaneously drives a conveyor belt connecting soft plate 4-5 and a pressing connecting plate 4-6 to synchronously move, the pressing connecting plate 4-6 also spaces materials on the conveyor belt 4-4, when the pressing connecting plate 4-6 moves to the position of the sliding inclined plate 4-7, the sliding inclined plate 4-7 is pressed upwards, the sliding inclined plate 4-7 drives the inclined plate connecting plate a4-8 and the inclined plate connecting plate b4-9 to move synchronously, the inclined plate connecting plate a4-8 also drives the inclined plate sliding column 4-10 to move upwards and can reset under the action of the pressing reset spring 4-12, when the pressing connecting plate 4-6 moves to contact with the inclined plate connecting plate b4-9, the materials on the conveyor belt 4-4 are pressed, one part of the pressed materials are discharged through the gap between the inclined plate connecting plate a4-8 and the next pressing connecting plate 4-6, and the other part of the pressed materials are discharged through the pressing glue discharging holes 4-13 and the pressing rubber discharging pipes 4-14 to the connecting side plates 1-14 and the side plates 1-14 In the space formed by the connecting plates c1-16, the connecting plates d1-17 and the connecting plates e1-18, the extrusion density of the materials is increased in the process, the conveyor belt 4-4 continues to move, the pressing connecting plate 4-6 breaks through the position of the sliding inclined plate 4-7 to the position above the pressing discharge inclined plate 4-15, and the materials pressed into the plate are inclined out through the pressing discharge inclined plate 4-15.

The sixth specific implementation mode:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, and 15, and further described in the present embodiment, in which any point on each of the longitudinal crushing blades 2 to 6 is connected clockwise as a thread.

The working principle of the device is as follows: the device can crush wood into boards, the wood is placed on a feeding inclined plate 1-12, the wood is inclined downwards through the feeding inclined plate 1-12, a transverse motor 1-1 works, the transverse motor 1-1 works to drive a transverse motor shaft 1-2 to rotate, the transverse motor shaft 1-2 rotates to drive a transverse transmission shaft a1-4 to rotate through a transverse belt a1-3, a transverse transmission shaft a1-4 rotates to drive a transverse transmission shaft c1-11 to rotate through a transverse belt b1-7, the transverse transmission shaft a1-4 and the transverse transmission shaft c1-11 simultaneously drive two rotary columns 1-5 to rotate in a forward direction and a reverse direction, the rotary columns 1-5 drive crushing cutters 1-6 to rotate when rotating, the wood is crushed into boards when the crushing cutters 1-6 rotate, the crushed wood can be crushed into small blocks by the equipment through the downward inclination of the output blocks 1-21, the crushed wood which is downwards inclined by the output blocks 1-21 is inclined into the longitudinal crushing grooves 2-7 through the longitudinal connecting plates 2-8, at the moment, the longitudinal motor 2-1 works to drive the longitudinal motor shaft 2-2 to rotate, the longitudinal motor shaft 2-2 rotates to drive the longitudinal transmission shaft 2-4 to rotate through the longitudinal belt 2-3, the longitudinal transmission shaft 2-4 rotates to drive the longitudinal transmission column 2-5 to rotate, the longitudinal transmission column 2-5 rotates to drive the longitudinal thread crushing cutter 2-6 to rotate, the longitudinal thread crushing cutter 2-6 rotates to crush the wood crushed into small blocks, and the small blocks of the wood are conveyed to the longitudinal motor 2-1 direction under the action of the longitudinal thread crushing cutter 2-6, when the wood chips are conveyed to the gap between the longitudinal crushing tank 2-7 and the connecting plate b1-15 to be discharged, the chips fall downwards and incline downwards under the action of the longitudinal output block 2-9, the equipment can stir the wood chips and the adhesive, the chips which incline downwards through the longitudinal output block 2-9 fall into the stirring barrel 3-9, the adhesive is injected into the stirring barrel 3-9 through the feeding pipe 3-10, the longitudinal motor 2-1 rotates to drive the stirring transmission shaft a3-2 to rotate through the stirring belt a3-1, the stirring transmission shaft a3-2 rotates to drive the stirring transmission shaft b3-4 to rotate through the stirring belt b3-3, the stirring belt b3-3 also drives the stirring friction wheel 3-5 to rotate during movement, the stirring friction wheel 3-5 rotates to drive the stirring transmission shaft c3-6 to rotate, the stirring transmission shaft c3-6 rotates to drive the stirring plate 3-8 to rotate, the stirring plate 3-8 rotates to uniformly stir the wood small blocks and the adhesive in the space formed by the stirring barrel 3-9 and the stirring barrel bottom plate 3-13, the handle 3-11-1 is pulled, the handle 3-11-1 moves to drive the sliding door 3-11-2 and the sliding door connecting plate 3-11-3 to move, the sliding door connecting plate 3-11-3 moves to press the limiting block 3-11-4 to move towards the limiting block 3-11-6, when the sliding door connecting plate 3-11-3 moves to the upper limiting block 3-11-4 and the upper limiting block 3-11-8, the sliding door 3-11-2 is opened, the limiting block 3-11-4 can be reset under the action of the limiting spring 3-11-7, after the sliding door 3-11-2 is opened, stirred materials in a space formed by the stirring barrel 3-9 and the stirring barrel bottom plate 3-13 flow out through an opening on the stirring barrel 3-9, the equipment can press the stirred wood and adhesive mixture into a synthetic board, the flowing mixture inclines downwards to the conveyor belt 4-4 through the stirring output inclined plate 3-12, at the moment, the transverse motor 1-1 rotates clockwise, the transverse motor 1-1 rotates to drive the pressing transmission shaft 4-2 to rotate through the pressing belt 4-1, the pressing transmission shaft 4-2 drives the pressing rotary column 4-3 to rotate, the pressing rotary column 4-3 rotates to drive the pressing rotary column 4-3 on the other side to rotate through the conveyor belt 4-4, and the conveyor belt 4-4 has the function of the conveyor belt when the pressing rotary column 4-3 rotates, the materials on the conveyor belt 4-4 are conveyed towards the direction of the pressing discharge inclined plate 4-15, the conveyor belt 4-4 simultaneously drives the conveyor belt connecting soft plate 4-5 and the pressing connecting plate 4-6 to synchronously move when moving, the pressing connecting plate 4-6 simultaneously spaces the materials on the conveyor belt 4-4, when the pressing connecting plate 4-6 moves to the position of the sliding inclined plate 4-7, the sliding inclined plate 4-7 is pressed upwards, the sliding inclined plate 4-7 drives the inclined plate connecting plate a4-8 and the inclined plate connecting plate b4-9 to synchronously move, the inclined plate connecting plate a4-8 also drives the inclined plate sliding column 4-10 to move upwards and can reset under the action of the pressing reset spring 4-12, when the pressing connecting plate 4-6 moves to contact with the inclined plate b connecting plate 4-9, the materials on the conveyor belt 4-4 are extruded, one part of the extruded materials is discharged through a gap between the inclined plate connecting plate a4-8 and the next pressing connecting plate 4-6, the other part of the extruded materials is discharged into a space formed by the connecting side plates 1-14, the connecting plates c1-16, the connecting plates d1-17 and the connecting plates e1-18 through the pressing rubber discharge holes 4-13 and the pressing rubber discharge pipes 4-14, the extrusion density of the materials is increased in the process, the conveyor belt 4-4 continues to move, the pressing connecting plate 4-6 breaks through the position of the sliding inclined plate 4-7 until the position is above the pressing discharge inclined plate 4-15, and the materials pressed into the plate are inclined out through the pressing discharge inclined plate 4-15.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (6)

1. The utility model provides a multi-functional wood working equipment for building, includes horizontal broken mechanism (1), vertical broken mechanism (2), rabbling mechanism (3), pressing mechanism (4), its characterized in that: the horizontal crushing mechanism (1) is connected with the vertical crushing mechanism (2), the vertical crushing mechanism (2) is connected with the stirring mechanism (3), the stirring mechanism (3) is connected with the horizontal crushing mechanism (1), the pressing mechanism (4) is connected with the horizontal crushing mechanism (1), and the stirring mechanism (3) is connected with the pressing mechanism (4).

2. The multifunctional wood working apparatus for construction as set forth in claim 1, wherein: the transverse crushing mechanism (1) comprises a transverse motor (1-1), a transverse motor shaft (1-2), a transverse belt a (1-3), a transverse transmission shaft a (1-4), a rotary column (1-5), a crushing cutter (1-6), a transverse belt b (1-7), a transverse transmission shaft b (1-8), a transverse transmission gear a (1-9), a transverse transmission gear b (1-10), a transverse transmission shaft c (1-11), a feeding inclined plate (1-12), a connecting plate a (1-13), a connecting side plate (1-14), a connecting plate b (1-15), a connecting plate c (1-16), a connecting plate d (1-17), a connecting plate e (1-18), a connecting plate f (1-19), a connecting plate g (1-20), The device comprises an output block (1-21), a transverse motor (1-1) is connected with a transverse motor shaft (1-2), the transverse motor shaft (1-2) is connected with a transverse belt a (1-3) in a friction mode, the transverse belt a (1-3) is connected with a transverse transmission shaft a (1-4) in a friction mode, the transverse transmission shaft a (1-4) is connected with a rotating column (1-5), the rotating column (1-5) is connected with a crushing cutter (1-6), the transverse belt b (1-7) is connected with a transverse transmission shaft a (1-4) in a friction mode, a transverse transmission shaft b (1-8) is connected with a transverse belt b (1-7) in a friction mode, a transverse transmission gear a (1-9) is connected with a transverse transmission shaft b (1-8), and a transverse transmission gear b (1-10) is meshed with a transverse transmission gear a (1-9), a transverse transmission shaft c (1-11) is connected with a transverse transmission gear b (1-10), a feeding inclined plate (1-12) is connected with a connecting plate a (1-13), the connecting plate a (1-13) is connected with a connecting side plate (1-14), the connecting side plate (1-14) is connected with a connecting plate b (1-15), the connecting plate b (1-15) is connected with a connecting plate c (1-16), the connecting plate c (1-16) is connected with a connecting plate d (1-17), the connecting plate d (1-17) is connected with a connecting side plate (1-14), a connecting plate e (1-18) is connected with a connecting side plate (1-14), a connecting plate f (1-19) is connected with a connecting side plate (1-14), and a connecting plate g (1-20) is connected with a connecting side plate (1-14), the output block (1-21) is connected with a connecting plate a (1-13), the connecting plate a (1-13) is connected with a connecting plate g (1-20), a connecting side plate (1-14) is connected with a transverse motor (1-1), the connecting side plate (1-14) is connected with a transverse transmission shaft a (1-4) through a bearing, the connecting side plate (1-14) is connected with a transverse transmission shaft b (1-8) through a bearing, the connecting side plate (1-14) is connected with a transverse transmission shaft c (1-11), the connecting side plate (1-14) is connected with a feeding inclined plate (1-12), the connecting side plate (1-14) is connected with a connecting plate c (1-16), the connecting plate b (1-15) is connected with a connecting plate f (1-19), the connecting plate b (1-15) is connected with the output block (1-21), the connecting plates c (1-16) are connected with the connecting plates d (1-17), the connecting plates c (1-16) are connected with the connecting plates e (1-18), the connecting plates d (1-17) are connected with the connecting plates f (1-19), and the connecting plates g (1-20) are connected with the connecting plates a (1-13).

3. The multifunctional wood working apparatus for construction as set forth in claim 1, wherein: the longitudinal crushing mechanism (2) comprises a longitudinal motor (2-1), a longitudinal motor shaft (2-2), a longitudinal belt (2-3), a longitudinal transmission shaft (2-4), a longitudinal transmission column (2-5), a longitudinal thread crushing cutter (2-6), a longitudinal crushing groove (2-7), a longitudinal connecting plate (2-8) and a longitudinal output block (2-9), wherein the longitudinal motor (2-1) is connected with the longitudinal motor shaft (2-2), the longitudinal motor shaft (2-2) is in friction connection with the longitudinal belt (2-3), the longitudinal belt (2-3) is in friction connection with the longitudinal transmission shaft (2-4), the longitudinal transmission shaft (2-4) is connected with the longitudinal transmission column (2-5), and the longitudinal transmission column (2-5) is connected with the longitudinal thread crushing cutter (2-6), the longitudinal thread crushing cutter (2-6) is connected with the longitudinal crushing groove (2-7) in a sliding mode, the longitudinal crushing groove (2-7) is connected with a longitudinal connecting plate (2-8), the longitudinal connecting plate (2-8) is connected with a connecting side plate (1-14), a longitudinal output block (2-9) is connected with the connecting side plate (1-14), a longitudinal motor (2-1) is connected with a connecting plate b (1-15), a longitudinal transmission shaft (2-4) is connected with a connecting plate a (1-13) through a bearing, the longitudinal transmission shaft (2-4) is connected with a connecting plate b (1-15) through a bearing, the longitudinal crushing groove (2-7) is connected with a connecting plate b (1-15), the longitudinal connecting plate (2-8) is connected with a connecting side plate (1-14), the longitudinal connecting plate (2-8) is connected with a connecting plate b (1-15), the longitudinal output blocks (2-9) are connected with the connecting plates b (1-15).

4. The multifunctional wood working apparatus for construction as set forth in claim 1, wherein: the stirring mechanism (3) comprises a stirring belt a (3-1), a stirring transmission shaft a (3-2), a stirring belt b (3-3), a stirring transmission shaft b (3-4), a stirring friction wheel (3-5), a stirring transmission shaft c (3-6), a stirring bearing plate (3-7), a stirring plate (3-8), a stirring barrel (3-9), a feeding pipe (3-10), a stirring barrel sliding door mechanism (3-11), a stirring output inclined plate (3-12) and a stirring barrel bottom plate (3-13), wherein the stirring belt a (3-1) is in friction connection with the stirring transmission shaft a (3-2), the stirring transmission shaft a (3-2) is in friction connection with the stirring belt b (3-3), and the stirring belt b (3-3) is in friction connection with the stirring transmission shaft b (3-4), a stirring transmission shaft b (3-4) is in bearing connection with a connecting plate a (1-13), a stirring friction wheel (3-5) is in friction connection with a stirring belt b (3-3), a stirring transmission shaft c (3-6) is in friction connection with the stirring friction wheel (3-5), a stirring bearing plate (3-7) is in bearing connection with the stirring transmission shaft c (3-6), a stirring plate (3-8) is in connection with the stirring transmission shaft c (3-6), a stirring barrel (3-9) is in sliding connection with the stirring plate (3-8), a feeding pipe (3-10) is in connection with the stirring barrel (3-9), a stirring barrel sliding door mechanism (3-11) is in connection with the stirring barrel (3-9), a stirring output inclined plate (3-12) is in connection with the connecting plate b (1-15), the connecting plate a (1-13) is in connection with the stirring barrel (3-9), the stirring belt a (3-1) is in friction connection with the longitudinal transmission shaft (2-4), the stirring transmission shaft a (3-2) is in bearing connection with the connecting plate a (1-13), the stirring transmission shaft a (3-2) is in bearing connection with the connecting plate b (1-15), the stirring transmission shaft b (3-4) is in bearing connection with the connecting plate b (1-15), and the stirring barrel (3-9) is connected with the connecting side plate (1-14); the stirring barrel sliding door mechanism (3-11) comprises a handle (3-11-1), a sliding door (3-11-2), a sliding door connecting plate (3-11-3), a limiting block (3-11-4), a limiting shaft (3-11-5), a limiting plate (3-11-6), a limiting spring (3-11-7), an upper limiting block (3-11-8) and a sliding limiting block (3-11-9), wherein the handle (3-11-1) is connected with the sliding door (3-11-2), the sliding door (3-11-2) is connected with the sliding door connecting plate (3-11-3), the sliding door connecting plate (3-11-3) is connected with the limiting block (3-11-4) in a sliding way, the limiting block (3-11-4) is connected with the limiting shaft (3-11-5), the limiting shaft (3-11-5) is connected with the limiting block (3-11-6) in a sliding mode, the limiting block (3-11-6) is connected with the stirring barrel (3-9), the limiting spring (3-11-7) is sleeved on the limiting shaft (3-11-5) and limited on the limiting block (3-11-4) and the limiting block (3-11-6), the upper limiting block (3-11-8) is connected with the limiting block (3-11-6), the sliding limiting block (3-11-9) is connected with the sliding door (3-11-2) in a sliding mode, and the sliding door (3-11-2) is connected with the stirring barrel (3-9) in a sliding mode.

5. The multifunctional wood working apparatus for construction as set forth in claim 1, wherein: the pressing mechanism (4) comprises a pressing belt (4-1), a pressing transmission shaft (4-2), a pressing rotary column (4-3), a transmission belt (4-4), a transmission belt connecting soft plate (4-5), a pressing connecting plate (4-6), a sliding inclined plate (4-7), an inclined plate connecting plate a (4-8), an inclined plate connecting plate b (4-9), an inclined plate sliding column (4-10), a pressing sliding plate (4-11), a pressing reset spring (4-12), a pressing rubber discharge hole (4-13), a pressing rubber discharge pipe (4-14) and a pressing discharge inclined plate (4-15), the pressing belt (4-1) is in friction connection with the pressing transmission shaft (4-2), and the pressing transmission shaft (4-2) is connected with the pressing rotary column (4-3), the pressing rotary column (4-3) is in friction connection with the conveyor belt (4-4), the conveyor belt (4-4) is connected with the conveyor belt connecting soft plate (4-5), the conveyor belt connecting soft plate (4-5) is connected with the pressing connecting plate (4-6), the pressing connecting plate (4-6) is connected with the conveyor belt (4-4), the sliding inclined plate (4-7) is connected with the inclined plate connecting plate a (4-8), the inclined plate connecting plate a (4-8) is connected with the inclined plate connecting plate b (4-9), the inclined plate connecting plate b (4-9) is connected with the sliding inclined plate (4-7), the inclined plate sliding column (4-10) is connected with the inclined plate connecting plate a (4-8), and the pressing sliding plate (4-11) is in sliding connection with the inclined plate sliding column (4-10), the pressing reset spring (4-12) is sleeved on the inclined plate sliding column (4-10) and is limited to be connected with the inclined plate connecting plate a (4-8) and the pressing sliding plate (4-11), the pressing rubber discharge hole (4-13) is formed in the conveyor belt connecting soft plate (4-5), the pressing rubber discharge pipe (4-14) is in sliding connection with the conveyor belt connecting soft plate (4-5), the pressing discharge inclined plate (4-15) is connected with the connecting side plate (1-14), the pressing belt (4-1) is in friction connection with the transverse transmission shaft c (1-11), the pressing transmission shaft (4-2) is connected with the connecting side plate (1-14), the conveyor belt connecting soft plate (4-5) is in sliding connection with the connecting side plate (1-14), the pressing connecting plate (4-6) is in sliding connection with the sliding inclined plate (4-7), the pressing sliding plates (4-11) are connected with the connecting side plates (1-14), the pressing sliding plates (4-11) are connected with the stirring output sloping plates (3-12), and the pressing rubber discharge pipes (4-14) are connected with the connecting side plates (1-14).

6. The multifunctional wood working apparatus for construction as set forth in claim 1, wherein: any point on each longitudinal thread crushing knife (2-6) is connected clockwise to form a thread line.

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