KR20240043308A - Manufacturing method and system for automatically fusing LPM plywood sheets - Google Patents

Abstract

The present invention relates to a manufacturing method and system for automatically fusing LPM plywood sheets, which have been improved to enable high-pressure fusing of LPM sheets to plywood so that the LPM sheets can be firmly fused and produced fully automatically.
In the present invention, the plywood (H) at the top among the plywood (H) loaded on the upper loading plate (11) of the plywood loading and lifting means (10) is moved to one side by the pushing port (24) of the plywood transport means (20). A loading transfer process (S1) that causes the plywood (H) to move, and a pair of brushes (31) rotated by a motor and a power transmission means to remove dust from both sides of the plywood (H) while removing the transfer roller (32). ), and the dust removal process (S2) to move in one direction by the plywood (H) transferred to the plurality of rollers (42) on the upper part of the support (41) is moved to the sheet stacking section (46) by the plywood transfer table (43). ) and the sheet (S) adsorbed to the air suction port (55) in the rotary cylinder (54) on the lower side of the pneumatic cylinder (53) that moves back and forth along the transfer port (52) (S3). The rear end (Sc) is adsorbed, the rotary cylinder (54) is rotated at a 90-degree angle and moved to one side so that the back side (Sb) of the sheet (S) is turned over and moved upward, and then the rotary cylinder (54) is moved. Rotate the air suction port (55) in the vertical direction, adsorb the front end (Sd) of the sheet (S) and move it in one direction, so that the back side (Sb) of the sheet (S) is opened on both sides of the plywood (H). After the LPM sheet stacking process (S4) to enable fusion, and the plywood (H) is heat-sealed between the upper and lower heat-pressed parts (61, 62) of the heat-sealing means (60), both sides of the reciprocating table (65) A heat bonding process (S5) in which the plywood (H) is adsorbed by the air suction port 68 and moves to one side to escape, and a plurality of rollers (S5) in which the plywood (H) is rotated by a motor and a power transmission means. The LPM plywood outer surface cleaning process (S6) carried out by moving along 71) and cutting the outer surface of the sheet while passing through the flexible cutter 73 provided on the support 72 on one side, and the roller 71 It is made to include an LPM plywood transfer and loading process (S7) in which the existing plywood (H) is adsorbed by the air suction port (81), moved to one side, and then loaded on the plywood loading and lifting means (10').

Description

Manufacturing method and system for automatically fusing LPM plywood sheets}

The present invention relates to LPM plywood, and more specifically, to a manufacturing method and system for automatically fusing LPM plywood sheets.

The prior art described as a patent document in the prior art literature has a problem in that the quality of LPM plywood is deteriorated because the LPM sheet (hereinafter referred to as sheet) has the disadvantage of not being hot fused tightly.

In addition, because the structure has poor performance for mass production, breakdowns occur frequently, requiring frequent maintenance, which leads to a decrease in productivity.

KR 10-1717950 B1 2017.03.20

The purpose of the present invention is to provide a manufacturing method and system for automatically fusing LPM plywood sheets, which have been improved to enable high-pressure fusing of LPM sheets to plywood, allowing the LPM sheets to be firmly fused to plywood and to be produced fully automatically. .

The present invention includes a loading and transport process in which the plywood at the top of the plywood loaded on the upper loading plate of the plywood loading and lifting means is moved to one side by the pushing tool of the plywood transport means, and the plywood is moved by a motor and a power transmission means. A dust removal process involves removing dust from both sides of the plywood by a pair of rotating brushes and moving it in one direction by a transfer roller, and plywood transferred to a number of rollers on the upper part of the support is moved to the sheet stacking section by a plywood transfer unit. In the direction change transfer process that causes the transfer to occur, the rear end of the sheet is adsorbed to the air suction port in the rotary cylinder on the lower side of the pneumatic cylinder that reciprocates along the moving tool, and the rotary cylinder is rotated at a 90-degree angle and moved to one side, so that the back side of the sheet is After turning it upside down and moving it, rotate the rotary cylinder so that the air suction port is in the vertical direction, adsorb the front end of the sheet and move it in one direction so that the back side of the sheet can be heat-sealed to both sides of the plywood. An LPM sheet stacking process, and a heat bonding process in which the plywood is heat-sealed between the upper and lower heat-pressed parts of the heat-sealing means, and then the plywood is adsorbed by the air suction ports on both sides of the reciprocating table and moved to one side to escape. , the LPM plywood outer surface cleaning process carried out by plywood moving along a plurality of rollers rotated by a motor and power transmission means and passing through a flexible cutter provided on a support on one side to cut the outer surface of the sheet, and the rollers It is characterized by a manufacturing method for automatically fusing LPM plywood sheets, which includes an LPM plywood transfer and loading process in which the plywood is adsorbed by an air suction port, moved to one side, and then loaded on the plywood loading and lifting means.

In addition, the present invention includes a plywood loading lifting means that moves the plywood at the top of the plywood loaded on the upper loading plate to one side by the pushing tool of the plywood transport means, and a pair of plywood in which the plywood is rotated by a motor and a power transmission means. A dust removal means that removes dust from both sides of the plywood with a brush and moves it in one direction by a transfer roller, and a dust removal means that allows the plywood transferred to the plurality of rollers on the upper part of the support to be transferred to the sheet stacking section by the plywood transfer unit. The rear end of the sheet is adsorbed to the air suction port in the rotary cylinder on the lower side of the pneumatic cylinder that reciprocates along the direction change means and the moving tool, and the rotary cylinder is rotated at a 90-degree angle and moved to one side, so that the back side of the sheet faces upward. After being turned over and moved, the rotary cylinder is rotated so that the air suction port is in a vertical direction, and the front end of the sheet is adsorbed and moved in one direction, so that the back side of the sheet can be heat-sealed to both sides of the plywood. And, after the plywood is heat-sealed between the upper and lower heat-compression parts, the plywood is adsorbed by the air suction ports on both sides of the reciprocating table and moves to one side to escape, and the plywood is connected to the motor and power transmission means. Plywood transfer and sheet side cutting means are carried out by moving along a plurality of rollers rotated by and cutting the outer surface of the sheet while passing through a flexible cutter provided on a support on one side, and the plywood on the rollers is placed in the air suction port. Another feature is a manufacturing system that automatically fuses LPM plywood sheets, which includes plywood adsorption and transfer means that adsorb and move to one side and then load the plywood loading and lifting means.

The direction change means has a plurality of rollers on the upper part of the support, and a plywood transfer table is provided between the rollers to move in the up and down direction by a raising and lowering cylinder, and the plywood transfer unit is operated by a motor and a power transmission means. Another feature is that it is configured to move horizontally along a guide.

The sheet stacking means has a moving tool that reciprocates in the horizontal direction along a guide guide by a motor and a power transmission means, and at the bottom of the moving tool, there is a pneumatic cylinder controlled by a pneumatic unit, and a lower support of the pneumatic cylinder is provided. Another feature is that it is provided with a rotary cylinder that reciprocates at an angle of 90 degrees, and a plurality of air suction ports are provided on one side of the rotary cylinder.

Another feature of the thermal fusion means 60 is that it has upper and lower thermal compression parts through which hot water heated in a boiler is circulated, and the upper thermal compression part is reciprocated in the up and down direction by a press cylinder.

Another feature of the heat fusion means is that it is provided with a reciprocating movable table that reciprocates in the longitudinal direction along both side guides of the press, and a plurality of air suction ports on both sides of the reciprocating table that are rotated by operating tables linked by pneumatic cylinders. Do it as

Another feature is that the plywood is moved upward from one side of the plywood transport and sheet outer side cutting means, and the outer side of the sheet is cut by a flexible cutter.

The plywood adsorption and transfer means is such that the air suction port for adsorbing the plywood on the roller is moved up and down by a pneumatic cylinder, and the pneumatic cylinder reciprocates to the upper part of the plywood loading lifting means along a guide guide by a motor and a power transmission means. What it consists of has different characteristics.

Since the present invention can high-pressure fuse LPM sheets to plywood, the LPM sheets are firmly fused and have the effect of improving quality.

In addition, since LPM sheets are produced fully automatically when heat-sealed to plywood, costs are reduced and excellent external competitiveness is secured.

1 is a block diagram showing the manufacturing method according to the present invention;
Figure 2 is a front view showing the overall system diagram of the present invention;
3 is a plan view showing the overall system diagram of the present invention;
Figure 4 is a side view showing the overall system diagram of the present invention;
Figure 5 is a front view showing the plywood loading and lifting means of the present invention;
Figure 6 is a side view of the plywood loading lifting means of the present invention in a lowered state;
Figure 7 is a front view of the plywood loading lifting means of another embodiment of the present invention in a lowered state;
Figure 8 is a side view of the plywood loading lifting means of another embodiment of the present invention in a lowered state;
Figure 9 is a front view showing the individual plywood transport means of the present invention.
Figure 10 is a plan view showing the individual plywood transport means of the present invention.
11 is a front configuration diagram showing the dust removal means of the present invention;
Figure 12 is a front view showing the direction changing means of the present invention.
Figure 13 is a plan view showing the direction changing means of the present invention.
Figure 14 is a side view showing the direction changing means of the present invention;
Figure 15 is a front view showing the sheet stacking section of the present invention;
Figure 16 is a front view showing the sheet stacking means of the present invention;
17 is a plan view showing the sheet stacking means of the present invention;
Figure 18 is a side view of the sheet stacking means of the present invention;
19 is a view explaining the operation of the sheet stacking means of the present invention;
Figure 20 is a view explaining the lamination state of the sheet and plywood of the present invention;
Figure 21 is a diagram illustrating the state in which the sheets of the present invention are transferred upside down and stacked;
Figure 22 is a diagram illustrating the state in which the sheet of the present invention is transported with its surface facing upward;
Figure 23 is a side view showing the heat fusion means of the present invention;
Figure 24 is a diagram explaining the operation of the adsorption means of the present invention;
Figure 25 is a front view of the plywood transport and sheet outer side cutting means of the present invention;
Figure 26 is a plan view showing the plywood transport and sheet outer side cutting means of the present invention;
Figure 27 is a front view showing the plywood adsorption and transport means of the present invention;
Figure 28 is a side view showing the plywood adsorption and transport means of the present invention.

The present invention will be described in more detail based on the attached preferred embodiment drawings as follows.

In the present invention, the fact that the motor power is driven by a pulley, belt, gear, chain gear, chain, or other power transmission means may be collectively described as "motor and power transmission means", and the air cylinder is used in a pneumatic unit. Since it is operated by , description and reference numerals related thereto may be omitted. And LPM plywood can be called plywood and LPM sheet can be described as a sheet. In addition, since the air suction port absorbs air by the air unit, the object is adsorbed to the air suction port, so the description of the pressure air unit that causes this action can be omitted.

Therefore, referring to Figure 1, the present invention includes a loading transfer process (S1), a dust removal process (S2), a direction change transfer process (S3), an LPM sheet stacking process (S4), a heat bonding process (S5), and The manufacturing process is carried out by the LPM plywood outer side arrangement process (S6) and the LPM plywood transport and loading process (S7).

In the loading and transferring process (S1), as shown in FIGS. 2 and 3 and FIGS. 5 and 6, a plurality of plywood (H) is loaded on the upper loading plate (11) of the plywood loading and lifting means (10), The plywood loading lifting means 10 moves the upper loading plate 11 upward or downward as the X-shaped lift 12 is operated in a closed and open state by the hydraulic cylinder 13, Since this is an already known lifting means, detailed operation description will be omitted.

The plywood loading and lifting means (10) is operated so that the uppermost plywood (H) is always positioned at the same height by moving it upward by a moving distance equal to the thickness of the plywood each time one plywood (H) is transferred. The operation is controlled by a control unit (not shown).

In addition, the plywood loading and lifting means 10 may further include rollers 14 on the upper surface of the upper loading plate 11, as shown in FIGS. 7 and 8.

Figures 9 and 10 show the plywood transport means (20). As shown in FIG. 9, the plywood transfer means 20 has a push port 24 at the lower part of the reciprocating transfer port 23 that reciprocates along the guide 22 by the pneumatic cylinder 21 to separate plywood ( H) It is moved by pushing one end to one side.

Therefore, in the loading and transferring process (S1), the plywood (H) at the top of the plywood (H) loaded on the upper loading plate (11) of the plywood loading and lifting means (10) is moved to one side by the pushing tool (24). It is a process.

The dust removal process (S2) of the present invention is carried out. In the dust removal process (S2), as shown in FIG. 11, dust on the plywood (H) is removed by a pair of brushes (31) rotated by a motor and a power transmission means in the dust removal means (30). It is removed and moved in one direction by the transfer roller 32.

Next, in the present invention, a direction change transfer process (S3) is performed. The direction change transfer process (S3) is carried out by the direction change means 40 as shown in FIGS. 12 and 13. There are a plurality of rollers 42 on the upper part of the support 41, and the rollers 42 A plywood transfer table 43 is provided between them and is moved in the up and down directions by a raising and lowering cylinder 44, and the plywood transfer unit 43 moves horizontally along the guide guide 45 by a motor and a power transmission means. It is capable of moving in any direction.

Therefore, the plywood (H) transferred from the dust removal means (30) is in contact with the roller (42) as shown at 12, and is lowered between the rollers (42) on the plywood transfer table (43). It stays in position.

In the above state, as the plywood transfer table 43 moves upward due to the operation of the elevating and lowering cylinder 44, the plywood H is free from interference with the roller 42, and in this state, the plywood H is moved by the motor and power transmission means. As shown by the imaginary line in FIG. 14, the plywood transfer table 43 is moved to one side so as to be placed on the sheet stacking unit 46 as shown in FIGS. 4 and 15. And after the movement is completed, it is moved back to its original state.

Next, the LPM sheet stacking process (S4) of the present invention is performed. The above process is carried out by the sheet stacking means 50 as shown in FIGS. 16 to 20.

As shown in Figures 16 to 19, the sheet stacking means 50 has a moving tool 52 that moves back and forth in the horizontal direction along the guide guide 51 by a motor and a power transmission means, and the moving tool 52 At the bottom, there is a pneumatic cylinder 53 controlled by a pneumatic unit (not shown), and the pneumatic cylinder lower support 57 is provided with a rotary cylinder 54 that reciprocates at an angle of 90 degrees, and the rotary cylinder ( 54) One side is provided with a plurality of air suction ports (55). The pneumatic cylinder 53 moves the rotary cylinder 54 in the vertical direction.

On the other hand, since each sheet (S) is heat-sealed on both sides of the plywood (H) as shown in (b) of Figure 20, the back side (Sb) of the sheet (S) on the lower side of the plywood (H) must face upward. And, the upper sheet (S) is heat-sealed in a laminated state with the surface facing toward the upper side.

However, as shown in Figure 20 (a), the surface (Sa) of the sheet (H) is toward the upper side, and the back side (Sb) is toward the lower side, as shown in Figure 20 (a). They are stacked facing this way.

Therefore, as shown in FIG. 19, the sheet stacking means 50 of the present invention first attaches the air suction port 55 to the sheet (S) in a state in which the air suction port 55 is positioned in the vertical direction as shown by the solid line in FIG. 19. After the rear end (Sc) of the sheet (S) is adsorbed and the rotary cylinder (54) is rotated at an angle of 90 degrees, the rear end (Sc) of the sheet (S) is bent upward as shown in the phantom line in FIG. It becomes a rising state.

In the above state, when the pneumatic cylinder 53 moves toward one side (to the right in the drawing) as shown in FIG. 21, the rear end Sc of the seat S moves and the seat S is turned over, which causes the seat When placed on the stacking unit 46, it is completely flipped over, and in this state, if the plywood (H) is stacked on top of the flipped sheet (S) as shown in (b) of Figure 20, the sheet (S) The back side (Sb) is laminated in contact with the plywood (H).

In the above state, the pneumatic cylinder 53 is moved so that the air suction port 55 adsorbs the front end portion Sd of another sheet s as shown in FIG. 22 and moves to the sheet stacking plate 56, and then moves to the sheet stacking plate 56 (Figure 20). When it is laminated on the upper surface of the plywood (H) as shown in b), in this case, the back side (Sb) of the sheet (S) is laminated in a state in contact with the plywood (H), so the back side (Sb) of the sheet (S) is laminated on both sides of the plywood (H). Sb) are automatically stacked so that they are all in contact.

Accordingly, the plywood (H), which is laminated so that the back surface (Sb) of the sheet (S) is all in contact, is laminated on the transfer belt 47 of the sheet lamination section 46, and is laminated on the sheet lamination section 47 by the motor and power transmission means. As shown in FIGS. 22 and 22B, (46) is in the form of a square frame, and the entire body is moved to the upper part of the lower thermal compression portion 62 of the thermal fusion means 60, and then the lower thermal compression is performed by driving the transfer belt 47. The plywood (H) on which the sheet (S) is laminated is moved and placed on the upper surface of the unit (62).

Next, a thermal bonding process (S5) is performed, in which the heat bonding process includes an upper thermal compression portion 61 and a lower thermal compression portion 62 through which hot water heated in a boiler (not shown) is circulated. This is carried out by means of fusion (60).

The heat fusion means 60 has upper and lower heat compression parts 61 and 62, as shown in FIGS. 22 and 23, and the upper heat compression part 61 is lifted up and down by the press cylinder 63. It is operated to move downward, and as a result, the plywood (H) in the lower thermal compression portion 62 is heated and the sheets (S) are heat-sealed to both sides of the plywood (H).

And on the press both side guides 64, a rectangular frame-shaped reciprocating table 65 is movable by a motor and a power transmission means, and on both sides of the reciprocating moving table 65, as shown in FIG. 24, pneumatic cylinders 66 are installed. There is an operating table 67 that is moved in a straight direction by ) and an air suction port 68 that is rotated by the operating table 67.

Therefore, when the heat fusion of the sheet (S) to the plywood (H) is completed and the upper thermal compression portion 61 is moved upward as shown in FIG. 23, the air suction port 68 is rotated from the virtual line state to the solid line state. After adsorbing the plywood (H), the reciprocating moving table 65 moves to one side as shown in FIG. 22b, and then the air suction force is released to place the plywood (H) on the roller conveyor 70 shown in FIG. 25. Then, the reciprocating moving table 65 is moved to return to the point where the lower thermal compression portion 62 is located.

Next, in the present invention, the LPM plywood outer surface preparation process (S6) is performed. In the LPM plywood outer surface arrangement process (S6), as shown in FIGS. 25 and 26, the plywood (H) is moved along a plurality of rollers 71 rotated by a motor and power transmission means, and a support 72 is provided on one side. Plywood transfer and sheet side cutting means 70 allow the outer side of the sheet to be cut while passing through the flexible cutter 73 provided in .

At this time. As the plywood (H) is moved upward from one side of the plywood transfer and sheet side cutting means (70) by being adsorbed by the air suction port (81) as shown in FIG. 27, the sheet (S) is cut by the flexible cutter (73). The outer surface is cut.

Next, the plywood (H) is loaded on the plywood loading and lifting means (10') by the plywood adsorption and transport means (80), which adsorbs the plywood (H) on the roller (71) by the air suction port (0) and moves it to one side. The LPM plywood transport and loading process (S7) is carried out.

In the plywood adsorption and transfer means 80, the air suction port 81 for adsorbing the plywood H on the roller 71 is moved in the vertical direction by a pneumatic cylinder 82, and the pneumatic cylinder 82 is operated by a motor. It is configured to reciprocate to the upper part of the stage (1x0') as shown in FIG. 28 along the guide guide 83 by means of power transmission. Since the plywood loading and lifting means 10' has the same configuration as the plywood loading and lifting means 10 described above, detailed description will be omitted.

The present invention is not necessarily limited to what is shown and described in the drawings, and may be modified and implemented in various forms by those skilled in the art to which the present invention pertains, so it should be broadly protected as long as it does not significantly depart from the scope of the claims. This is self-evident.

10.10'Plywood loading lifting means 20: Individual plywood transport means
30: Dust removal means 40: Direction change means
46: Sheet stacking unit 50: Sheet stacking means
60: Heat fusion means 70: Plywood transfer and sheet outer side cutting means
80: Plywood adsorption transport means S1: Loading transport process
S2: Dust removal process S3: Direction change transfer process
S4: LPM sheet lamination process S5: Thermal bonding process
S6: LPM plywood outer side arrangement process S7: LPM plywood transfer and loading process

Claims (8)

Among the plywood (H) loaded on the upper loading plate (11) of the plywood loading and lifting means (10), the plywood (H) at the top is moved to one side by the pusher (24) of the plywood transport means (20). Transfer process (S1);
Dust removal in which the plywood (H) is moved in one direction by the transfer roller (32) while removing dust from both sides of the plywood (H) by a pair of brushes (31) rotated by a motor and a power transmission means. Process (S2) and;
A direction change transfer process (S3) in which the plywood (H) transferred to the plurality of rollers (42) on the upper part of the support unit (41) is transferred to the sheet stacking unit (46) by the plywood transfer unit (43);
The rear end (Sc) of the sheet (S) is adsorbed to the air suction port (55) in the rotary cylinder (54) on the lower side of the pneumatic cylinder (53) that reciprocates along the moving port (52), and the rotary cylinder (54) Rotate it at an angle of 90 degrees and move it to one side so that the back surface (Sb) of the sheet (S) is flipped and moved toward the upper direction. Then, the rotary cylinder (54) is rotated so that the air suction port (55) is vertical. and an LPM sheet stacking process (S4) in which the front end portion (Sd) of the sheet (S) is adsorbed and moved in one direction so that the back side (Sb) of the sheet (S) can be heat-sealed to both sides of the plywood (H). ;
After the plywood (H) is heat-sealed between the upper and lower heat-pressed parts (61, 62) of the heat-sealing means (60), the plywood (H) is fused through the air suction ports (68) on both sides of the reciprocating moving table (65). A thermal bonding process (S5) in which this is adsorbed and moved to one side to escape;
The plywood (H) moves along a plurality of rollers (71) rotated by a motor and power transmission means and passes through a flexible cutter (73) provided on one side of the supporter (72), thereby cutting the outer surface of the sheet. The LPM plywood outer surface preparation process (S6) is carried out;
Including an LPM plywood transfer and loading process (S7) in which the plywood (H) on the roller (71) is adsorbed by the air suction port (81), moves to one side, and is then loaded on the plywood loading and lifting means (10'). A manufacturing method that automatically fuses LPM plywood sheets.
Plywood loading and lifting means (10) for moving the uppermost plywood (H) among the plywood (H) loaded on the upper loading plate (11) to one side by the pushing port (24) of the plywood transport means (20);
Dust removal in which the plywood (H) is moved in one direction by the transfer roller (32) while removing dust from both sides of the plywood (H) by a pair of brushes (31) rotated by a motor and a power transmission means. Sudan (20) and;
Direction changing means 40 for transferring the plywood H transferred to the plurality of rollers 42 on the support 41 to the sheet stacking unit 46 by the plywood transfer 43;
The rear end (Sc) of the sheet (S) is adsorbed to the air suction port (55) in the rotary cylinder (54) on the lower side of the pneumatic cylinder (53), which reciprocates along the moving port (52), and the rotary cylinder (54) Rotate it at an angle of 90 degrees and move it to one side so that the back surface (Sb) of the sheet (S) is flipped and moved toward the upper direction. Then, the rotary cylinder (54) is rotated so that the air suction port (55) is in the vertical direction. a sheet stacking means (50) for adsorbing the front end portion (Sd) of the sheet (S) and moving it in one direction so that the back surface (Sb) of the sheet (S) can be heat-sealed to both sides of the plywood (H);
After the plywood (H) is heat-sealed between the upper and lower heat compression parts (61, 62), the plywood (H) is adsorbed by the air suction ports (68) on both sides of the reciprocating table (65) and moved to one side. Heat fusion means (60) for escaping;
The plywood (H) moves along a plurality of rollers (71) rotated by a motor and power transmission means and passes through a flexible cutter (73) provided on one side of the supporter (72), thereby cutting the outer surface of the sheet. Plywood transfer and sheet side cutting means (70) implemented;
It is configured to include a plywood adsorption and transfer means (80) that causes the plywood (H) on the roller (71) to be adsorbed by the air suction port (81), moved to one side, and then loaded on the plywood loading and lifting means (10'). A manufacturing system that automatically fuses LPM plywood sheets.
According to claim 2,
The direction change means (40) has a plurality of rollers (42) on the upper part of the support (41), and a plywood transfer table (43) is provided between the rollers (42) to move in the upper and lower direction by the elevating and lowering cylinder (44). A manufacturing system for automatically welding LPM plywood sheets, wherein the plywood transfer table 43 is configured to move horizontally along the guide 45 by a motor and a power transmission means.

According to claim 2,
The sheet stacking means 50 has a moving tool 52 that reciprocates in the horizontal direction along the guide 51 by a motor and a power transmission means, and a pneumatic unit (not shown) is located at the lower part of the moving tool 52. There is a pneumatic cylinder 53 controlled by the pneumatic cylinder, and the pneumatic cylinder lower support 57 is equipped with a rotary cylinder 54 that reciprocates at an angle of 90 degrees, and a plurality of air cylinders are installed on one side of the rotary cylinder 54. A manufacturing system for automatically fusing LPM plywood sheets, characterized by being provided with a suction port (55).
According to claim 2,
The heat fusion means 60 has upper and lower heat compression parts 61 and 62 through which hot water heated in the boiler is circulated, and the upper heat compression part 61 is moved up and down by the press cylinder 63. A manufacturing system that automatically fuses LPM plywood sheets, characterized in that it is configured to move in a reciprocating manner.
According to claim 2,
The heat fusion means (60) is operated by a reciprocating moving table (65) that reciprocates in the longitudinal direction along the press both side guides (64), and pneumatic cylinders (66) on both sides of the reciprocating moving table (65). A manufacturing system for automatically fusing LPM plywood sheets, characterized by having a plurality of air suction ports (68) rotated by a stand (67).
According to claim 2,
The LPM plywood sheet is characterized in that the outer surface of the sheet (S) is cut by the flexible cutter (73) while the plywood (H) is moved upward from one side of the plywood transfer and sheet side cutting means (70). Manufacturing system that automatically fuses.
According to clause 2,
In the plywood adsorption and transfer means 80, the air suction port 81 for adsorbing the plywood H on the roller 71 is moved in the vertical direction by a pneumatic cylinder 82, and the pneumatic cylinder 82 is operated by a motor. A manufacturing system for automatically welding LPM plywood sheets, characterized in that it is configured to reciprocate to the upper part of the plywood loading and lifting means (10') along the guide guide (83) by a power transmission means.