CN116690736B - High-stability waterproof MGO floor production equipment and production process thereof - Google Patents

Abstract

The invention relates to the technical field of wood floor production, in particular to high-stability waterproof MGO floor production equipment and a production process thereof, wherein the equipment comprises a support frame a and a support frame b, a rotation mechanism a is arranged on the support frame a, a rotation mechanism b is arranged on the support frame b, a plurality of support tables are arranged on the rotation mechanism a in a sliding manner, a jacking assembly is arranged on the support tables, the rotation mechanism a drives a wood board a to do rotation motion, the rotation mechanism b drives the wood board b to do rotation motion through the action of a negative pressure assembly, gluing of the wood board a is completed under the action of a gluing assembly, the wood board a and the wood board b are pressed through the jacking action of the jacking assembly, and the wood board a and the wood board b are heated and pressurized through a pressing assembly to complete floor molding; the supporting table jacks up the pushing block through the jacking block in the moving process, so that the rubber box is driven to rise, the rubber material flows onto the rubber coating roller from the rubber outlet, excessive rubber material on the rubber coating roller due to direct current of the rubber material is avoided, and the rubber coating of the rubber coating roller is more uniform.

Description

High-stability waterproof MGO floor production equipment and production process thereof

Technical Field

The invention relates to the technical field of wood floor production, in particular to high-stability waterproof MGO floor production equipment and a production process thereof.

Background

The utility model discloses a spc floor forming device, which comprises a conveying framework, wherein driving rollers are rotationally arranged between two opposite upright posts of the conveying framework, support columns are fixedly arranged on two sides of the top end of a hot pressing workbench, the two support columns are connected with a movable plate in an inserted mode, a heating plate is connected with the middle of the bottom end of the movable plate in a threaded mode, a hydraulic push rod is arranged at the bottom end of the top plate in a fixed mode, and a roller coating mechanism is fixedly arranged in the middle of the top end of the conveying framework.

However, the inventor finds that the glue in the feeding box body of the equipment flows out to the glue spreader all the time when the equipment is operated in the production process of the existing equipment, so that the glue is excessively smeared unevenly in the glue spreading process, and the floor directly enters the hot pressing workbench after being smeared, so that the position deviation is easy to occur in the pressing process, and the product percent of pass is lower.

Disclosure of Invention

The invention aims at overcoming the defects of the prior art, by arranging the lower end part of the glue box into an arc surface with the same diameter as the glue spreader, the glue box can be attached to the glue spreader when glue spreading is stopped, glue can not overflow, the problem that glue in the feeding box of the equipment flows out to the glue spreader all the time when the equipment runs, excessive glue is coated unevenly in the glue spreading process is solved, the jacking assembly is arranged on the supporting table in a sliding way, when the jacking assembly moves to the jacking section, the glued wood board a is jacked up, the wood board a and the wood board b are subjected to primary lamination, and when the wood board b and the wood board b enter the lamination assembly, the left end part of the lamination assembly guides and corrects the wood board a and the wood board b, and the problem that the floor directly enters a hot pressing workbench after glue spreading is solved, the position deviation easily occurs in the lamination process, and the product qualification rate is lower is solved.

Aiming at the technical problems, the invention adopts the following technical scheme:

The utility model provides a waterproof MGO floor production facility of high stability, includes support frame a and support frame b, be provided with slewing mechanism a on the support frame a, be provided with slewing mechanism b on the support frame b, be provided with a plurality of brace table on the slewing mechanism a, it is provided with jacking subassembly to slide on the brace table, be provided with negative pressure subassembly on the slewing mechanism b, support frame a has set gradually rubber coating subassembly from left to right, puts thing platform and pressfitting subassembly, be provided with the cylinder that promotes plank b on putting the thing platform, support frame a middle part is provided with the guide rail, slewing mechanism a drives plank a and is slewing motion, and slewing mechanism b drives plank b through the effect of negative pressure subassembly and is slewing motion, accomplishes plank a rubber coating under the effect of rubber coating subassembly to through jacking effect with plank a and plank b pressfitting, and accomplish the floor shaping through pressfitting subassembly to plank a and plank b heating pressurization.

Preferably, the rotary mechanism a comprises a rotary assembly a and a rotary assembly b which are arranged on the support frame a, the rotary assembly a comprises a motor a and a rotary chain a driven by the motor a, the rotary assembly b comprises a transmission shaft a and a rotary chain b driven by the transmission shaft a, and the rotary assembly a and the rotary assembly b synchronously operate.

Preferably, the revolving mechanism b comprises a revolving assembly c and a revolving assembly d which are arranged on the supporting frame b, the revolving assembly c comprises a motor b and a revolving chain c driven by the motor b, the revolving assembly d comprises a transmission shaft b and a revolving chain d driven by the transmission shaft b, and the revolving assembly c and the revolving assembly d synchronously run.

Preferably, the supporting table is provided with a placement groove, a slot hole is formed in the middle of the placement groove, and top blocks are arranged on the front side and the rear side of the supporting table.

Preferably, the jacking assembly comprises a top plate slidably arranged on the slot, a fixed block arranged at the lower end part of the top plate and a return spring arranged between the top plate and the fixed block.

Preferably, the negative pressure assembly comprises a negative pressure plate arranged on the rotary mechanism b, a negative pressure cover arranged at the middle part of the rotary mechanism b and a negative pressure pipe arranged on the negative pressure cover.

As a preference, the rubber coating subassembly is including setting up fixed plate on support frame a, rotating the rubber coating roller of setting on the fixed plate and sliding the gluey box of setting in rubber coating roller upper end, set up on the fixed plate and supplied gluey box gliding sliding tray, the cambered surface diameter of end is the same with the rubber coating roller diameter under the gluey box, the gum outlet has been seted up to the end under the gluey box, both sides all are provided with the pushing block with kicking block matched with around the gluey box.

Preferably, the upper end of the guide rail is provided with a gluing section, a transition section, a jacking section and a pressing section in sequence from left to right.

As still another preferable aspect, the press-fit assembly includes a support plate provided on the support frame a and a press-fit member provided on the support plate.

The invention also aims to provide a production process of the high-stability waterproof MGO floor, which comprises the following steps of:

a. A feeding procedure, namely, manually placing a wood board a and a wood board b on a supporting table at the left end part of the rotary mechanism a and a placing platform respectively to finish feeding;

b. A gluing procedure, namely driving the supporting table to do rotary motion by the rotary mechanism a under the action of the motor a, so as to drive the wood board a to do rotary motion, jacking the glue box through the jacking block to enable glue to flow onto the glue spreader from the glue outlet, and driving the wood board a to rotate after passing through the glue spreader to finish gluing the wood board a;

c. A primary pressing procedure, namely when the rotating mechanism a drives the wood board a to move to the transition section, the wood board b is pushed to the lower end part of the negative pressure plate through the air cylinder, the wood board b is adsorbed to the negative pressure plate under the action of the negative pressure cover, the rotating mechanism b drives the wood board b to perform rotating motion, and the jacking component jacks the wood board a through the jacking section, so that the primary pressing with the wood board b is completed;

d. A heating and pressing procedure, wherein the rotating mechanism a drives the wood board a and the wood board b to move to a pressing section, and pressing of the wood board a and the wood board b is completed through the heating and pressing action of the pressing component;

e. and a blanking process, namely manually taking down the wood board a and the wood board b which move to the right end part of the rotary mechanism a to finish blanking, and finishing floor molding.

The invention has the beneficial effects that:

1. According to the invention, the lower end part of the glue box is set to be the cambered surface with the same diameter as the glue spreader, so that the glue box can be attached to the glue spreader when the glue spreading is stopped, glue can not overflow, and the glue spreader can spread more uniformly.

2. According to the invention, the jacking assembly is arranged on the supporting table in a sliding manner, so that when the jacking assembly moves to the jacking section, the glued wood board a is jacked up, the glued wood board a and the glued wood board b are subjected to preliminary lamination, and when the glue is fed into the lamination assembly, the left end part of the lamination assembly guides and corrects the glue and the wood board b, so that the qualification rate of products is improved.

3. According to the invention, the supporting table is provided with the jacking blocks at the front side and the rear side, and the pushing blocks are jacked up by the jacking blocks in the moving process of the supporting table, so that the rubber material is driven to ascend to flow onto the rubber coating roller from the rubber outlet, and the situation that the rubber material on the rubber coating roller is excessive due to the fact that the rubber material is directly discharged is avoided, and the rubber coating of the rubber coating roller is more uniform is avoided.

In conclusion, the equipment has the advantages of being even in gluing, improving the product qualification rate and the like, and is particularly suitable for the technical field of wood floor production.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly described below, it being obvious that the drawings described below are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a high stability waterproof MGO flooring production facility;

fig. 2 is a schematic structural diagram of the swing mechanism a and the pressing assembly;

FIG. 3 is an enlarged view of FIG. 2A;

Fig. 4 is a schematic structural view of the swing mechanism b and the negative pressure assembly;

FIG. 5 is a schematic view of a structure of a support table;

FIG. 6 is a schematic structural view of a jacking assembly;

FIG. 7 is a schematic view of the structure of the guide rail;

FIG. 8 is a diagram of the operating state of a highly stable waterproof MGO flooring production device;

fig. 9 is a flow chart of a process for producing a highly stable waterproof MGO floor.

1. Support frame a, support frame b, support frame 3, rotary mechanism a, rotary mechanism b, support frame 5, lifting assembly 6, negative pressure assembly 7, glue applying assembly 8, guide rail 9, pressing assembly 10, negative pressure plate 20, negative pressure cover 30, wooden plate a, rotary assembly 31, rotary assembly a, rotary assembly 32, rotary assembly b, motor a, rotary chain a, 321, transmission shaft a, 322, rotary chain b, 40, wooden plate b, 41, rotary assembly c, 42, rotary assembly d, 411, motor b, 412, rotary chain c, 421, transmission shaft b, 422, rotary chain d, 50, air cylinder 51, placing groove 52, slot hole 53, top block 61, top plate 62, fixing block 63, return spring 71, negative pressure plate 72, negative pressure cover 73, negative pressure pipe 81, fixing plate 82, glue applying roller 83, glue box 811, sliding groove 831, pushing block 91, glue applying section 92, transition section 93, lifting section 94, pressing section 101, pressing member 102.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below with reference to the accompanying drawings.

Example 1

As shown in fig. 1 to 9, a high-stability waterproof MGO floor production device comprises a support frame a1 and a support frame b2, wherein a rotation mechanism a3 is arranged on the support frame a1, a rotation mechanism b4 is arranged on the support frame b2, a plurality of support tables 5 are arranged on the rotation mechanism a3, a jacking component 6 is slidably arranged on the support tables 5, a negative pressure component 7 is arranged on the rotation mechanism b4, a gluing component 8, an object placing platform 20 and a pressing component 10 are sequentially arranged on the support frame a1 from left to right, an air cylinder 50 for pushing a wood board b40 is arranged on the object placing platform 20, a guide rail 9 is arranged in the middle of the support frame a1, the rotation mechanism a3 drives the wood board a30 to do rotation motion, the rotation mechanism b4 drives the wood board b40 to do rotation motion through the action of the negative pressure component 7, the gluing of the wood board a30 is completed under the action of the gluing component 8, the jacking component 6 is used for pressing the wood board a30 and the wood board b40, and the pressing component 10 is used for pressing the wood board b 30 and the wood board b40 is heated to complete floor molding.

It should be mentioned here that, through sliding the jacking subassembly 6 that sets up on supporting bench 5 for when jacking subassembly 6 moved to jacking section 93, jack-up the plank a30 that accomplishes the rubber coating, make it accomplish preliminary pressfitting with plank b40, when reentrant pressfitting subassembly 10, the left end of pressfitting subassembly 10 leads to correct both, is favorable to improving the qualification rate of product.

As shown in fig. 2, the revolving mechanism a3 comprises a revolving assembly a31 and a revolving assembly b32 which are arranged on a supporting frame a1, the revolving assembly a31 comprises a motor a311 and a revolving chain a312 driven by the motor a311, the revolving assembly b32 comprises a transmission shaft a321 and a revolving chain b322 driven by the transmission shaft a321, and the revolving assembly a31 and the revolving assembly b32 synchronously operate.

As shown in fig. 4, the revolving mechanism b4 comprises a revolving assembly c41 and a revolving assembly d42 which are arranged on the supporting frame b2, the revolving assembly c41 comprises a motor b411 and a revolving chain c412 driven by the motor b411, the revolving assembly d42 comprises a transmission shaft b421 and a revolving chain d422 driven by the transmission shaft b421, and the revolving assembly c41 and the revolving assembly d42 synchronously operate.

In this example, the revolution speed of the revolution mechanism a3 and the revolution speed of the revolution mechanism b4 are the same, and both are operated in synchronization.

As shown in fig. 5, a placement groove 51 is formed in the support table 5, a slot hole 52 is formed in the middle of the placement groove 51, and top blocks 53 are arranged on the front side and the rear side of the support table 5.

It should be mentioned that, through all setting up kicking block 53 in both sides around brace table 5, brace table 5 is through kicking block 53 jack-up pushing block 831 in the removal in-process to drive gluey box 83 and rise and make the sizing material flow to glue spreader 82 from the glue outlet, avoid sizing material direct current to make glue spreader 82 go up the sizing material too much, make glue spreader 82 rubber coating more even.

As shown in fig. 6, the jacking assembly 6 includes a top plate 61 slidably provided on the slot 52, a fixed block 62 provided at a lower end portion of the top plate 61, and a return spring 63 provided between the top plate 61 and the fixed block 62.

In this example, a return spring 6 is disposed between the top plate 61 and the fixed block 62, so that the top plate 61 can return to the original position after being separated from the guide rail 9, and the top plate 61 can be kept from falling off in the original position when being turned to the lower end of the swing mechanism a 3.

As shown in fig. 4, the negative pressure assembly 7 includes a negative pressure plate 71 provided on the swing mechanism b4, a negative pressure cover 72 provided in the middle portion of the swing mechanism b4, and a negative pressure pipe 73 provided on the negative pressure cover 72.

In this example, the negative pressure plate 71 moves to the lower end of the negative pressure cover 72 to have a negative pressure effect and suck up the wooden board b40 pushed by the cylinder 50.

As shown in fig. 3, the glue coating assembly 8 includes a fixing plate 81 disposed on the supporting frame a1, a glue coating roller 82 rotatably disposed on the fixing plate 81, and a glue box 83 slidably disposed on an upper end portion of the glue coating roller 82, a sliding groove 811 for sliding the glue box 83 is formed in the fixing plate 81, a cambered surface diameter of a lower end portion of the glue box 83 is the same as a diameter of the glue coating roller 82, a glue outlet is formed in a lower end portion of the glue box 83, and pushing blocks 831 matched with the top blocks 53 are disposed on front and rear sides of the glue box 83.

It should be noted that, the lower end of the glue box 83 is set to be the cambered surface with the same diameter as the glue spreader 82, so that the glue box 83 can be attached to the glue spreader 82 when the glue spreading is stopped, the glue can not overflow, and the glue spreading of the glue spreader is more uniform.

As shown in fig. 7, the upper end of the guide rail 9 is provided with a glue spreading section 91, a transition section 92, a jacking section 93 and a pressing section 94 in this order from left to right.

As shown in fig. 2, the press-fit assembly 10 includes a support plate 101 provided on the support frame a1 and a press-fit member 102 provided on the support plate 101.

Example two

A production process of a high-stability waterproof MGO floor board comprises the following steps:

a. A feeding procedure, namely, manually putting a wood board a30 and a wood board b40 on a supporting table 5 at the left end part of a rotary mechanism a3 and a storage platform 20 respectively to finish feeding;

b. a gluing procedure, namely driving the supporting table 5 to perform rotary motion by the rotary mechanism a3 under the action of the motor a311, so as to drive the wood board a30 to perform rotary motion, lifting the glue box 83 through the jacking block 53 to enable glue to flow onto the glue spreader 82 from the glue outlet, and driving the wood board a30 to rotate after passing through the glue spreader 82 to finish gluing the wood board a 30;

c. a preliminary pressing procedure, wherein when the rotating mechanism a3 drives the wood board a30 to move to the transition section 92, the wood board b40 is pushed to the lower end part of the negative pressure plate 71 by the air cylinder 50, the wood board b40 is adsorbed to the negative pressure plate 71 under the action of the negative pressure cover 72, the rotating mechanism b4 drives the wood board b40 to perform rotating motion, and the jacking component 6 jacks up the wood board a30 through the jacking section 93, so that the wood board b40 and the wood board a30 are subjected to preliminary pressing;

d. a heating and pressing process, wherein the rotating mechanism a3 drives the wood board a30 and the wood board b40 to move to a pressing section 94, and pressing of the wood board a30 and the wood board b40 is completed through the heating and pressing action of the pressing assembly 10;

e. And a blanking process, namely manually taking down the wood board a30 and the wood board b40 which move to the right end part of the rotary mechanism a3 to finish blanking, and finishing floor molding.

The working process is as follows:

the supporting table 5 at the left end part of the rotary mechanism a3 is manually placed with the wood board a30 and the wood board b40 on the object placing platform 20 to finish feeding;

The motor a311 is started to drive the supporting table 5 on the revolving mechanism a3 to revolve, so as to drive the wood board a30 to revolve, the pushing block 831 is jacked up by the jacking block 53, so that the glue box 83 is driven to rise, the glue material flows onto the glue spreader 82 from the glue outlet, and the wood board a30 is driven to rotate after passing through the glue spreader 82 to finish gluing the wood board a 30;

When the rotary mechanism a3 drives the wood board a30 to move to the transition section 92, the wood board b40 pushes the wood board a30 to the lower end part of the negative pressure plate 71 through the air cylinder 50, the wood board b40 is adsorbed to the negative pressure plate 71 under the action of the negative pressure cover 72, the rotary mechanism b4 drives the wood board b40 to perform rotary motion, and the jacking component 6 jacks the wood board a30 through the jacking section 93, so that the wood board a30 and the wood board b40 are subjected to preliminary lamination;

The rotary mechanism a3 drives the wood board a30 and the wood board b40 to move to the pressing section 94, pressing of the wood board a30 and the wood board b40 is completed through heating and pressing of the pressing assembly 10, and blanking is completed through manually taking down the wood board a30 and the wood board b40 which move to the right end part of the rotary mechanism a3, so that floor forming is completed.

Of course, in this disclosure, those skilled in the art will understand that the term "a" or "an" is to be interpreted as "at least one" or "one or more," i.e., in one embodiment, the number of elements may be one, and in another embodiment, the number of elements may be multiple, and the term "a" is not to be construed as limiting the number.

The foregoing is merely a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions easily conceivable by those skilled in the art under the technical teaching of the present invention should be included in the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the protection scope of the claims.

Claims (10)

1. A high-stability waterproof MGO floor production device comprises a support frame a (1) and a support frame b (2), and is characterized in that a rotary mechanism a (3) is arranged on the support frame a (1), a rotary mechanism b (4) is arranged on the support frame b (2), a plurality of support tables (5) are arranged on the rotary mechanism a (3), a jacking component (6) is arranged on the support tables (5) in a sliding manner, a negative pressure component (7) is arranged on the rotary mechanism b (4), a gluing component (8), a placement platform (20) and a pressing component (10) are sequentially arranged on the support frame a (1) from left to right, a cylinder (50) for pushing a wood board b (40) is arranged on the placement platform (20), a guide rail (9) is arranged at the middle part of the support frame a (1), the rotary mechanism a (3) drives the wood board a (30) to do rotary motion, the rotary mechanism b (40) is driven by the action of the negative pressure component (7), the gluing component (8) finishes the gluing component (30) and the jacking component (30) to jack the wood board by the action of the negative pressure component (40), and the wood board a (30) and the wood board b (40) are heated and pressurized through the pressing assembly (10) to finish floor molding.

2. The highly stable waterproof MGO floor production apparatus of claim 1, wherein the swivel mechanism a (3) includes a swivel assembly a (31) and a swivel assembly b (32) that are disposed on the support frame a (1), the swivel assembly a (31) includes a motor a (311) and a swivel chain a (312) driven by the motor a (311), the swivel assembly b (32) includes a transmission shaft a (321) and a swivel chain b (322) driven by the transmission shaft a (321), and the swivel assembly a (31) and the swivel assembly b (32) operate synchronously.

3. The highly stable waterproof MGO floor production apparatus of claim 1, wherein the swivel mechanism b (4) includes a swivel assembly c (41) and a swivel assembly d (42) that are disposed on the support frame b (2), the swivel assembly c (41) includes a motor b (411) and a swivel chain c (412) driven by the motor b (411), the swivel assembly d (42) includes a transmission shaft b (421) and a swivel chain d (422) driven by the transmission shaft b (421), and the swivel assembly c (41) and the swivel assembly d (42) operate synchronously.

4. The highly stable waterproof MGO floor production device according to claim 1, wherein the supporting table (5) is provided with a placing groove (51), a slot hole (52) is formed in the middle of the placing groove (51), and top blocks (53) are arranged on the front side and the rear side of the supporting table (5).

5. The highly stable waterproof MGO floor production apparatus as claimed in claim 1, wherein the jacking assembly (6) comprises a top plate (61) slidably disposed on the slot hole (52), a fixed block (62) disposed at a lower end portion of the top plate (61), and a return spring (63) disposed between the top plate (61) and the fixed block (62).

6. The highly stable waterproof MGO floor production apparatus as claimed in claim 1, wherein the negative pressure assembly (7) comprises a negative pressure plate (71) provided on the swing mechanism b (4), a negative pressure cover (72) provided at a middle portion of the swing mechanism b (4), and a negative pressure pipe (73) provided on the negative pressure cover (72).

7. The high-stability waterproof MGO floor production equipment according to claim 1, wherein the gluing component (8) comprises a fixed plate (81) arranged on the support frame a (1), a gluing roller (82) arranged on the fixed plate (81) in a rotating mode and a glue box (83) arranged at the upper end portion of the gluing roller (82) in a sliding mode, a sliding groove (811) for the glue box (83) to slide is formed in the fixed plate (81), the cambered surface diameter of the lower end portion of the glue box (83) is the same as the diameter of the gluing roller (82), a glue outlet is formed in the lower end portion of the glue box (83), and pushing blocks (831) matched with the top blocks (53) are arranged on the front side and the rear side of the glue box (83).

8. The high-stability waterproof MGO floor production device according to claim 1, wherein the upper end of the guide rail (9) is provided with a gluing section (91), a transition section (92), a jacking section (93) and a pressing section (94) in sequence from left to right.

9. The highly stable waterproof MGO floor production apparatus as claimed in claim 1, wherein the press-fit assembly (10) comprises a support plate (101) provided on the support frame a (1) and a press-fit member (102) provided on the support plate (101).

10. A production process of a high-stability waterproof MGO floor board comprises the following steps:

a. A feeding procedure, namely finishing feeding by manually placing a wood board a (30) on a supporting table (5) at the left end part of a rotary mechanism a (3) and placing a wood board b (40) on a storage platform (20);

b. a gluing procedure, namely driving the supporting table (5) to perform rotary motion by the rotary mechanism a (3) under the action of the motor a (311), so as to drive the wood board a (30) to perform rotary motion, lifting the glue box (83) through the jacking block (53) to enable glue to flow onto the glue spreader (82) from the glue outlet, and driving the wood board a (30) to rotate after passing through the glue spreader (82) to finish gluing the wood board a (30);

c. A preliminary pressing procedure, wherein a negative pressure plate (71) is arranged on a rotary mechanism b (4), when the rotary mechanism a (3) drives a wood plate a (30) to move to a transition section (92), the wood plate b (40) is pushed to the lower end part of the negative pressure plate (71) through an air cylinder (50), the negative pressure plate b is adsorbed to the negative pressure plate (71) under the action of a negative pressure cover (72), the rotary mechanism b (4) drives the wood plate b (40) to perform rotary motion, a jacking component (6) jacks up the wood plate a (30) through a jacking section (93) to complete preliminary pressing with the wood plate b (40), and the negative pressure plate (71) is separated from the negative pressure cover (72) so that the wood plate b (40) is separated from the negative pressure plate (71) to be adhered on the wood plate a (30);

d. A heating and pressing step, wherein the rotating mechanism a (3) drives the wood board a (30) and the wood board b (40) to move to a pressing section (94), and pressing of the wood board a (30) and the wood board b (40) is completed through the heating and pressing action of the pressing assembly (10);

e. and a blanking process, namely manually taking down the wood board a (30) and the wood board b (40) which move to the right end part of the rotary mechanism a (3) to finish blanking, and finishing floor molding.