JP2005297492A - Coating apparatus and apparatus for manufacturing laminated wood - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a coating apparatus capable of efficiently coating with an adhesive in a continuous carrying line, and an apparatus for manufacturing laminated wood. <P>SOLUTION: The coating apparatus 5 coating the faces to be stuck of laminae 9 of laminated wood 900 prepared by stacking and sticking a plurality of the laminae 9 with the adhesive, is equipped with a carrying part 31 for carrying the laminae 9, a coating part 32 for coating the faces to be stuck of the laminae 9 carried by the carrying part 31 with the adhesive, and a moving mechanism part 33 for moving the coating part 32 in the horizontal direction. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a coating apparatus and a laminated material manufacturing apparatus.

Conventionally, a laminated material composed of a plurality of laminaes includes an application process for applying an adhesive, a stacking process for stacking lamina coated with an adhesive, a pressing process for pressing the stacked lamina, and the like. It is manufactured after.
More specifically, in order to bond the lamina to each other in the application step, an adhesive is applied to the surfaces to be bonded, and in the stacking step, the lamina is brought into contact with the surface to which the adhesive has been applied. In a pressing process, a laminated material is manufactured by pressing and curing the laminated lamina from above and from the side to adhesively cure the adhesive between the laminas (for example, patents). Reference 1).
JP 2000-317918 A

  However, in the stacking process in the laminated timber manufacturing apparatus described in Patent Document 1, the lamina coated with an adhesive is stacked on the upper surface of the lamina disposed in the middle and lower portions of the laminated timber, and then the upper portion thereof. In order to stack the lamina where the adhesive is not applied, the transport line for transporting the lamina coated with the adhesive from the coating process to the stacking process, and the coating line separately from the transport line. It was necessary to provide a transport line capable of supplying lamina to the loading process without going through the process. For this reason, there is a problem that it is difficult to manufacture the laminated timber in one continuous line, and efficient stacking cannot be performed.

  An object of the present invention is to provide a coating apparatus and a laminated material manufacturing apparatus capable of efficiently applying an adhesive with one continuous conveyance line.

  In order to solve the above-described problems, the invention according to claim 1 is directed to a laminated material (for example, laminated material 900) of a laminated material (for example, laminated material 900) formed by stacking and laminating a plurality of laminated materials (for example, lamina 9). In a coating apparatus (for example, coating apparatus 3) for applying an adhesive to the bonding surface, a transport unit (for example, transport unit 31) that transports the lamina 9 and a lamina 9 that is transported by the transport unit 31 A coating unit (for example, a coating unit 32) that applies an adhesive to a surface to be bonded; and a moving unit (for example, a moving mechanism unit 33) that moves the coating unit 32 in a horizontal direction. Features.

According to the first aspect of the present invention, the application device 3 for applying the adhesive to the lamina 9 includes the conveyance unit 31, the application unit 32, and the moving means 33, and the lamina conveyed by the conveyance unit 31. 9, an adhesive is applied by the application unit 32, and the application unit 32 can be moved in the horizontal direction by the moving means 33.
Thereby, with respect to the lamina 9 to which the adhesive is not applied, the adhesive is not applied by moving the applying portion 32 in the horizontal direction by the moving means 33, and the lamina 9 is selectively applied. An adhesive can be applied to the adherend surface. That is, the lamina 9 to which the adhesive is applied and the lamina 9 to which the adhesive is not applied can be conveyed on the same conveyance line.
Accordingly, it is possible to efficiently apply the adhesive with one continuous conveyance line.

  According to a second aspect of the present invention, in the coating apparatus 3 according to the first aspect, the moving means 33 is a rail portion (for example, the rail portion 331) that extends in the horizontal direction so as to be separated from the transport portion 31. ) And a frame portion (for example, a frame portion 332) that is slidably provided on the rail portion 331 and connected to the application portion 32.

According to the invention described in claim 2, it is needless to say that the effect of the invention described in claim 1 can be obtained, in particular, only by sliding the frame part 332 in the horizontal direction along the rail part 331. As a result, the application unit 32 moves.
Thereby, the application part 32 can be moved easily and reliably, and selective application | coating of an adhesive agent can be performed easily and reliably.

  The invention according to claim 3 is the coating apparatus 3 according to claim 1 or 2, wherein the coating unit 32 includes predetermined coating means (for example, a coating roller 3211 and a support roller 3212), A coating main body (for example, a coating main body 321) provided so as to be positioned in the middle of the transport unit 31 at the time of coating, and the coating main body 321 when the coating main body 321 is detached from the transport unit 31. An auxiliary transport unit (for example, an auxiliary transport unit 322) that assists the transport of the lamina 9 is provided in the middle of the transport unit 31 by replacing the main body 321.

  Here, the state that “the coating main body is detached from the transport unit” means a state that “the coating main body is located outside the region where the lamina is transported”.

According to the invention described in claim 3, it is a matter of course that the effect of the invention described in claim 1 or 2 can be obtained, and in particular, the application part 32 includes an application main body 321, an auxiliary conveyance part 322, and Thus, the lamina 9 delivered from the transport unit 31 is transported by either the coating main body 321 or the auxiliary transport unit 322.
Thereby, even when application | coating of an adhesive agent is not performed, the lamina 9 will be conveyed reliably by being conveyed on the auxiliary conveyance part 322. FIG.

  In the invention according to claim 4, an adhesive is applied to the adherend surface of the laminated member (for example, laminated member 900) formed by stacking and laminating a plurality of laminated members (for example, laminated member 9). In the coating device (for example, the coating device 3), an adhesive is applied to the transport portion (for example, the transport portion 31) for transporting the lamina 9 and the adherend surface of the lamina 9 transported by the transport portion 31. First laminating portion (for example, first coating portion 32A) to be attached and the lamina 9 to be adhered, which is provided downstream of the first coating portion 32A and is transported by the transport portion 31 The second application part (for example, the second application part 32B) for applying an adhesive to the surface, the first application part 32A, and the second application part 32B are individually horizontal. Moving means (for example, the first moving mechanism unit 33A, the second moving mechanism unit 33B), Characterized in that it comprises.

According to the invention described in claim 4, the application device 3 includes the first application part 32A and the second application part 32B, and each application part moves independently in the horizontal direction. By being possible, not only two different types of adhesive components can be applied, but also whether or not two types of adhesive components are applied independently of each other without being affected by each other. It will be possible to judge.
Thereby, not only can an efficient bonding process be performed using two types of adhesive constituent materials, but also the first moving means 33A and the second moving means 33B can move the first The application body (for example, the application body 321) of each of the first application part 32A and the second application part 32B can be moved independently, thereby preventing useless application of adhesive. it can.

  A fifth aspect of the present invention is the coating apparatus 3 according to the fourth aspect, wherein either one of the first coating part 32A and the second coating part 32B is applied to the lamina 9. An adhesive is applied to the adherend surface, and a curing accelerator is applied to the adherend surface of the lamina 9 by the other application portion different from the one application portion.

According to the invention described in claim 5, it is needless to say that the effect of the invention described in claim 4 can be obtained. In particular, an adhesive and a curing accelerator can be used as two kinds of adhesive constituent materials. it can.
Thereby, the time required for curing of the adhesive can be shortened, and the laminated material can be manufactured in a shorter time.

  The invention according to claim 6 is the coating apparatus 3 according to claim 5, wherein the surface to be bonded of the lamina 9 to which the first coating unit 32A applies and the second coating unit. The surface to be bonded of the lamina 9 to which the coating is performed by 32B is a different surface.

According to the invention described in claim 6, the effect of the invention described in claim 5 is naturally obtained, and in particular, the adhesive and the curing accelerator are applied to different surfaces.
Thereby, the acceleration | stimulation hardening of the adhesive agent by a hardening accelerator will be started only after the to-be-bonded surfaces of the lamina 9 adhere | attach, and the adhesion fixation of the lamina 9 can be made stronger.

  Invention of Claim 7 is provided with the coating device 3 as described in any one of Claims 1-6, and is a laminated material by using the lamina 9 with which the adhesive agent was apply | coated by the said coating device 3 A laminated material manufacturing apparatus (for example, a laminated material manufacturing apparatus 100) characterized by manufacturing 900.

  According to the invention described in claim 7, the effect of the invention described in any one of claims 1 to 6 can be obtained, and at the same time, the time required for manufacturing the laminated material can be shortened. The laminated material 900 can be manufactured.

According to the present invention, the application device for applying the adhesive to the lamina comprises the conveyance unit, the application unit, and the moving means, and the lamina conveyed by the conveyance unit is coated with the adhesive by the application unit. The application portion can be moved in the horizontal direction by the moving means. As a result, for the lamina where the adhesive is not applied, the adhesive is not applied by moving the application portion in the horizontal direction by the moving means, and the lamina is selectively applied to the lamina's adherend surface. An adhesive can be applied. That is, the lamina to which the adhesive is applied and the lamina to which the adhesive is not applied can be conveyed on the same conveyance line. Accordingly, it is possible to efficiently apply the adhesive with one continuous conveyance line.
Further, the application portion moves only by sliding the frame portion in the horizontal direction along the rail portion. Thereby, the application part can be moved easily and reliably, and selective adhesive application can be easily and reliably performed.
Furthermore, since the coating unit is composed of the coating main body and the auxiliary transport unit, the lamina delivered from the transport unit is transported by either the coating main body or the auxiliary transport unit. Thereby, even when application | coating of an adhesive agent is not performed, lamina will be conveyed reliably by being conveyed on an auxiliary conveyance part.

The coating apparatus is provided with a first coating unit and a second coating unit, and each coating unit is independently movable in the horizontal direction, so that two different types of adhesive configurations are provided. Not only can the material be applied, but whether or not to apply the two types of adhesive constituent materials can be independently determined without being affected by each other. As a result, not only can an efficient bonding process be performed using two types of adhesive component materials, but also, each coating body can be moved independently by each moving means. , Can prevent wasteful adhesive application.
An adhesive and a curing accelerator can be used as the two types of adhesive constituent materials. Thereby, the time required for curing of the adhesive can be shortened, and the laminated material can be manufactured in a shorter time.
Furthermore, the adhesive and the curing accelerator are applied to different surfaces. Thereby, the hardening acceleration of the adhesive by the hardening accelerator is started only after the bonded surfaces of the lamina are bonded to each other, and the bonding and fixing of the lamina can be made stronger.
And by using the coating apparatus of this invention for a laminated material manufacturing apparatus, the time concerning laminated material manufacture can be shortened and a laminated material can be manufactured efficiently.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. However, the scope of the invention is not limited to the illustrated examples.
FIG. 1 is a diagram showing a main configuration of a laminated timber manufacturing apparatus exemplified as a preferred embodiment to which the present invention is applied.

  As shown in FIG. 1, a laminated material manufacturing apparatus 100 that manufactures a laminated material in which a plurality of laminaes to which an adhesive is applied is stacked and bonded to a surface to be bonded is provided. , A stacking device 4, a press device 5, a reversing device 6, a cutting device 7, a carry-out device 8, and the like. In addition, a length and the number of laminas 9 necessary for manufacturing a laminated material having a desired size are selected from the coarse material supply unit 1 and supplied via the carry-in device 2 to the laminated material manufacturing apparatus 100. The

Here, the laminated wood 900 and the lamina 9 will be described. The perspective view of the laminated material 900 was shown in FIG. The laminated material 900 shown in FIG. 2 (b) is formed from a plurality of laminas 9 as shown in FIG. 2 (a). Specifically, for example, it is formed from four laminae 9a, 9b, 9c, 9d. Here, 9a is a lamina located at the bottom of the laminated lumber 900, lamina 9b is located on the upper surface 92 side of lamina 9a, lamina 9c is located on the upper surface 92 side of lamina 9b, and lamina 9d is lamina 9c. Is located on the upper surface 92 side of the laminated material 900 and at the top of the laminated material 900. Moreover, the laminated material 900 is comprised by apply | coating an adhesive agent (illustration omitted) to the to-be-adhered surface of each lamina, and overlapping and adhering.
The lamina 9 is a plate material obtained by processing, for example, red pine, larch, fir, spruce, and other trees into a planar rectangular plate shape, and has a structure defined by JAS. In the present embodiment, the lamina 9 may be a square member instead of the plate member.

The carry-in device 2 is a device that carries the lamina supplied from the coarse material supply unit 1 into the laminated wood manufacturing apparatus 100. The carry-in device 2 is configured by a belt conveyer, a roller conveyer, or the like that can convey a target lamina in a certain direction. In the present embodiment, the carry-in device 2 is arranged at regular intervals and orthogonal to the conveyance direction. It is comprised by the roller rotated centering around a rotating shaft.
Further, the lamina 9 supplied from the coarse material supply unit 1 to the carry-in device 2 is transported one by one in a state where the longitudinal (length) direction of the lamina 9 and the transport direction are substantially parallel.

  The coating device 3 is a device that applies an adhesive or the like to the adherend surface of the lamina 9. In FIG. 3, the top view of the coating device 3 is shown.

The coating device 3 is a device for applying an adhesive or the like to the adherend surface of the lamina 9 of the laminated material 900 in which a plurality of laminas 9 are stacked and bonded. The applicator 3 horizontally transports the transport unit 31 for transporting the lamina 9, the application unit 32 for applying an adhesive to the adherend surface of the lamina 9 transported by the transport unit 31, and the application unit 32. Although provided with the movement mechanism part 33 as a movement means which can move to a direction, as shown in FIG. 3, the coating device 3 is provided with two application parts and a movement mechanism part in this Embodiment.
Specifically, the application unit 32 is more than the first application unit 32A and the first application unit 32A for applying an adhesive to the adherend surface of the lamina 9 conveyed by the conveyance unit 31. Provided on the downstream side of the lamina in the conveyance direction, the lamina 9 delivered by the conveyance unit 31 is provided with a second application part 32B for applying a curing accelerator as an adhesive to the adherend surface.
Further, the first application part 32A and the second application part 32B are provided independently, and the first moving mechanism part 33A is provided with the second application part 32A in the second application part 32A. The application part 32B is provided with a second movement mechanism part 33B, and the first movement mechanism part 33A and the second movement mechanism part 33B can individually move the application parts in the horizontal direction.

  The conveyance unit 31 has the same configuration as that of the carry-in device 2 described above, and is configured by rollers that are arranged at regular intervals and rotate about a rotation axis that is orthogonal to the conveyance direction. The lamina 9 is conveyed one by one in a state where the conveyance direction and the longitudinal direction of the lamina 9 are substantially parallel.

FIG. 4 shows an enlarged top view of the vicinity of the first applying portion 32A and the first moving mechanism portion 33A in FIG. 3, and FIG. 5 shows a front view of FIG.
As shown in FIGS. 4 and 5, the first application unit 32 </ b> A includes an application main body 321 provided so as to be positioned in the middle of the conveyance unit 31 during application, and the application main body 321 includes the conveyance unit 31. When it comes off, it is replaced with the coating body 321 and is located in the middle of the transport unit 31, and includes an auxiliary transport unit 322 that assists in transporting the lamina 9.

The coating body 321 includes a coating roller 3211 as a coating unit provided on the upper surface side of the lamina 9 to be transported, and a support roller 3212 that supports the lamina 9 to be transported from below.
The application roller 3211 plays a role of applying an adhesive to the lamina 9 and is provided at a height at which the lamina 9 can be in contact with the upper surface. Specifically, the application roller 3211 on which the adhesive is placed and the lamina 9 are in contact with each other, and the lamina 9 is conveyed while being in contact with each other, so that the application roller 3211 rotates on the surface to be bonded of the lamina 9. However, the adhesive is applied to the lamina 9.
That is, the coating roller 3211 is disposed so as to be in contact with the upper surface of the lamina 9 and the lamina 9 is allowed to pass therethrough, whereby the adhesive is applied to the upper surface of the lamina 9.
The support roller 3212 plays a role of supporting the lamina 9 when an adhesive is applied to the upper surface of the lamina 9 by the application roller 3211. The support roller 3212 is provided at substantially the same height as the rollers of the transport unit 31. At this time, the support roller 3212 supports the lamina 9 from below, and also serves as a guide for guiding the lamina 9 to which the adhesive is applied to the transport unit 31 again.

  The auxiliary conveyance unit 322 has the same configuration as the conveyance unit 31 described above, and includes a plurality of rollers that rotate about a rotation axis that is orthogonal to the lamina conveyance direction at regular intervals. In addition, the auxiliary conveyance unit 322 is replaced with the application main body 321 when the coating main body 321 is disengaged from the conveyance unit 31, that is, outside the region used for conveyance of the lamina 9. Located in the middle, assists in transporting the lamina 9.

  Next, the first moving mechanism unit 33A will be described. 33 A of 1st moving mechanism parts are provided with the rail part 331 extended in a horizontal direction so that it may space apart from the conveyance part 31, and the frame part 332 which was provided in the rail part 331 so that sliding was possible, and was connected with the coating main body 321. Consists of.

The rail portion 331 includes two rails 331a and 331a provided substantially parallel to each other in a direction substantially orthogonal to the lamina 9 conveyance direction.
Note that the rail portion 331 is not necessarily provided in a direction substantially orthogonal to the lamina 9 conveyance direction, and one of the coating body 321 and the auxiliary conveyance portion 322 is always conveyed by the lamina 9. It is sufficient if the arrangement can be arranged in the area provided for the above, and the arrangement can be replaced as necessary. Accordingly, the rail portion 331 may be provided so as to move at an angle of 45 ° with respect to the conveying direction of the lamina 9 or may be curved, for example.

The frame portion 332 is provided so as to stand up from the bottom surface portion 3321 in a direction substantially orthogonal to the longitudinal direction of the rail 331a at both ends of the bottom surface portion 3321 provided across the two rails 331a and 331a. The side wall portion 3322 is formed. The frame portion 332 is provided so as to be slidable on the rail portion 331.
The connection of the coating body 321 to the frame portion 332 is as follows. Two shafts are provided up and down from one side wall 3322 of the frame 332 to the other side wall 3322. A coating roller 3211 is attached to the upper one of the two shafts, and a support roller 3212 is attached to the lower shaft.
In addition, an auxiliary conveyance unit 322 is connected to the frame portion 332, and the auxiliary conveyance unit 322 can slide on the rail portion 331.
Therefore, when the frame portion 332 moves by sliding on the rail portion 331, the application main body 321 and the auxiliary conveyance portion 322 connected to the frame portion 332 also move in conjunction with the movement. That is, by moving the frame part 332 and the auxiliary conveyance part 322 on the rail part 331, it becomes possible to move the coating main body 321 and the auxiliary conveyance part 322 to a desired position.
The second application unit 32B and the second movement mechanism unit 33B are also substantially similar in configuration to the first application unit 32A and the first movement mechanism unit 33A, but in the second application unit 32B, The application roller 3211 is positioned below and the support roller 3212 is positioned above.

  Here, a honeymoon adhesive is mentioned as an adhesive used for this Embodiment. The honeymoon adhesive is composed of two types of adhesive constituent materials A and B which are applied to the upper surface 92 and the bottom surface 91 which are the surfaces to be bonded of the adjacent lamina 9 facing each other. For example, imide resin is used as the adhesive component A, glyoxal is used as the adhesive component B, or a polymer compound having an acetoacetyl group is used as the adhesive component A, and aldehyde is used as the adhesive component B A compound, a polyethyleneimine, or a hydrazine compound as a main component may be used. In short, the specific type of the adhesive is not particularly limited as long as it is an adhesive that rapidly gels or hardens when superposed on each other. Further, a curing agent that reacts with the adhesive constituent material A for improving water resistance and heat resistance may be mixed in advance and used.

In the present embodiment, a honeymoon adhesive composed of two types of adhesive constituent materials A and B is used. That is, of the opposite surfaces to be bonded of the lamina 9, an adhesive is applied to the bonded surface of one lamina 9, and a curing accelerator is applied to the bonded surface of the other lamina 9.
Specifically, the adhesive as the adhesive constituent material A is applied by the first application part 32A shown in FIG. 3, and as the adhesive constituent material B by the second application part 32B. The curing accelerator is applied. Further, depending on the first application portion 32A, application is performed on the upper surface 92 (see FIG. 2), which is one surface to be bonded of the lamina 9, and the other application portion of the lamina 9 is applied depending on the second application portion 32B. Application is performed on the bottom surface 91 which is the surface to be bonded. That is, an adhesive is applied to the upper surface 92 of the lamina 9 by the first application portion 32A, and a curing accelerator is applied to the bottom surface 91 of the lamina 9 by the second application portion 32B.

  The stacking device 4 is a device that stacks a plurality of laminas coated with an adhesive and a curing accelerator in a desired order. A side view of the stacking device 4 is shown in FIG. In FIG. 6, the stacking device 4 includes a casing 40 in which a linear alignment surface 40A is formed vertically, a moving mechanism 41 that moves the casing 40 back and forth as indicated by an arrow P, and an alignment surface 40A. Are provided with a plurality of rod-shaped holding portions 42 that can be moved in and out, and a protruding and retracting mechanism 43 that moves these holding portions 42 in and out of the alignment surface 40A.

The casing 40 is formed in a substantially box shape, and a cradle 44 for receiving the lamina 9 is provided at a lower portion along the alignment surface 40A. In order to horizontally hold the lamina 9 at a plurality of positions in the longitudinal direction, the holding portion 42 is a plurality of pairs arranged in the horizontal direction, and these holding portions 42 that are paired are arranged vertically. A plurality (six pairs in FIG. 6) are provided. The retracting mechanism 43 is composed of a cylinder device that drives the holding portion 42 forward and backward. The holding part 42 protrudes from the alignment surface 40A in the advanced state to hold the lamina 9 (see the imaginary line), and is stored in the casing 40 in the retracted state (see the solid line).
Note that two stacking devices 4 are provided in parallel, and the lamina 9 stacked by each stacking device 4 passes through two conveying paths 57 provided in correspondence with each other. It is conveyed to the press device 5.

The press device 5 is a device that applies pressure to a plurality of laminas 9 stacked by the stacking device 4 to bond the laminaes more strongly. A top view of the pressing device 5 is shown in FIG. Moreover, the side view of FIG. 7 is shown in FIG. 8, and sectional drawing in the AA 'line of FIG. 7 is shown in FIG.
Here, in the press device 5, the direction in which the lamina 9 is carried into the press device 5, that is, the longitudinal direction in the top view of FIG. 7 is “x direction”, and the direction substantially orthogonal to the x direction, ie, FIG. The short direction in the top view is described as “y direction”, and the direction substantially orthogonal to the plane formed by the x direction and y direction, that is, the short direction in the side view of FIG. 8 is described as “z direction”.
7-9, the press apparatus 5 is provided in the middle of the conveyance path 57 of the lamina 9 stacked by the stacking apparatus. The pressing device 5 is provided in parallel with a pressure-resistant wall 55 erected between the two conveyance paths 57, and can adjust the press length in multiple stages in the length direction of the lamina 9. 51, the side surface of a plurality of laminas 9 stacked, a side surface press part 52 whose press length can be adjusted in multiple stages in the length direction of the lamina 9, and detection as detection means for detecting the length of the lamina A sensor 53 and a protective cover 56 that covers the upper surface of the press device section are provided.

  The press part 51 is for pressing a plurality of stacked laminaes 9 in the stacking direction to bond and fix the laminaes together. A press plate positioned above the stacked laminaes 9 511 and a cylinder device 512 provided as a pressing unit that is provided at predetermined intervals in the length direction of the lamina 9 and presses the press plate 9 in the z direction.

  The press plate 511 is located above the lamina 9 loaded and carried in, and the length in the x direction is equal to or greater than the maximum length of the lamina 9 being conveyed. Further, the length (width) of the press plate 511 in the y direction is equal to or greater than the maximum width of the lamina 9 to be conveyed, and the pressure wall 55 and a side press plate 521 to be described later. In order to avoid interference, the distance between the pressure-resistant wall 55 and the side press plate 521 is shorter.

The cylinder device 512 is, for example, a hydraulic cylinder device, and includes a piston rod 5121 connected to a press plate 511.
The cylinder device 512 is provided above the protective cover 56 positioned above the pressure-resistant wall 55, and a plurality of cylinder devices 512 are provided at regular intervals in the x direction of the press device 5. In the present embodiment, for example, a total of 13 cylinder devices 512 of cylinder devices 512a, 512b,..., 512m are provided in the x direction from the side on which the lamina 9 is carried.

  The side press part 52 presses a plurality of stacked lamina 9 from the side direction, and the lamina 9 that may be generated by the displacement of the lamina 9 generated when the lamina 9 is stacked, or the press from above by the press part 51. The side press plate 521 located on the side of the plurality of laminas 9 stacked and the side press plate 521 in the y direction are provided at predetermined intervals in the length direction of the lamina. A side cylinder device 522 is provided as a side pressing means for pressing.

  The side press plate 521 is provided at a position facing the surface opposite to the surface facing the pressure-resistant wall 55 of the lamina 9 loaded and loaded. The length of the side press plate 521 in the x direction is equal to or longer than the allowable value of the length of the lamina 9 to be conveyed. The length of the side press plate 521 in the z direction is equal to or greater than the allowable height of the stacked lamina 9, and the upper end 521a of the side press plate 521 in the z direction is the press plate. It is located slightly above the lower end 511b in the z direction of 511. Further, the side press plate 521 also serves as a guide when the stacked lamina 9 is carried into the press device 5.

The side cylinder device 522 is, for example, a hydraulic cylinder device, and includes a side piston rod 5221 connected to the side press plate 521. Further, the side cylinder device 522 is provided on a side column 523 that is erected at regular intervals in the x direction of the press device 5.
Specifically, the side columns 523 are located outside the side press plate 521 in the y direction, are provided at regular intervals along the x direction of the press device 5, and from the side on which the lamina 9 is carried in, the side columns 523a, 523b,... 523h are arranged in total. Correspondingly, the side cylinder device 522 is provided with a total of eight side cylinder devices 522 including side cylinder devices 522a, 522b,. It will be.

The detection sensor 53 functions to detect the length of the lamina 9 that is carried in. In the present embodiment, the detection sensor 53 is attached adjacent to each side cylinder device 522 at the side column 523.
The detection sensor 53 is composed of, for example, an infrared sensor, and is provided so as to emit infrared light in a direction orthogonal to the loading direction of the lamina 9 (that is, the y direction). The detection sensor 53 includes a light emitting unit (not shown) and a light receiving unit (not shown), and whether or not the light receiving unit receives the reflected light returned by the infrared light emitted from the light emitting unit reflected by the pressure-resistant wall 55. Thus, the presence of the lamina 9 is detected. That is, when the lamina 9 is positioned in the infrared irradiation region, the light receiving unit of the detection sensor 53 does not receive infrared rays, and thus the information is output to the control unit 54 as detection information.
In the present embodiment, as shown in FIG. 8, for example, eight detection sensors (53a to 53h) are attached to each of the eight side pillars (523a to 523h).
In this embodiment, an infrared sensor is used as the sensor. However, a sensor such as a CCD camera that detects the lamina 9 as an image or a contact sensor may be used.

The control unit 54 includes a CPU (Central Processing Unit) 541, a RAM (Random Access Memory) 542, and a ROM (Read Only Memory) 543, as shown in the block diagram of the schematic configuration of the control unit 54 in FIG. .
The CPU 541 develops a program designated from various programs stored in the ROM 543 in the work area of the RAM 542, and executes various processes according to the program.
The RAM 542 forms a storage area for temporarily storing programs, data, and the like, a work area for executing the programs, and the like in various processes executed by the CPU 541.
The ROM 543 stores various programs necessary for executing the operation of the present invention, and stores, for example, a press unit control program 5431 and a side surface press unit control program 5432.

  The press part control program 5431 is a program for making a determination and instructing which cylinder apparatus to operate among a plurality of cylinder apparatuses based on the detection information detected by the detection sensor 53, and for controlling the side press part control. The program 5332 is a program that makes a determination and an instruction as to which of the plurality of side cylinder devices is to be operated based on the detection information detected by the detection sensor 53. The CPU 541 functions as a press control unit and a side press unit control unit by executing the press unit control program 5431 and the side press unit control program 5432.

The reversing device 6 is a device that lays down and reverses the laminated material units in order to convey the laminated material units composed of the stacked laminated materials 9 in the order according to the manufacturing order.
Here, the laminated material unit refers to a unit in which a plurality of laminated materials 9 are laminated, and more specifically refers to an aggregate of the laminated materials 9 pressed by the press device 5 by one press.
A top view of the reversing device 6 is shown in FIG. A side view of FIG. 11 is shown in FIG.
In FIG. 11, the laminated wood unit is conveyed from the lower side to the upper side of the drawing.
As shown in FIGS. 11 and 12, the reversing device 6 includes a first transport conveyor 61 that transports the laminated material unit 999 pressed by the press device 5 while standing, and transport of the first transport conveyor 61. The laying device 62 as a laying means for laying down the laminated timber unit 999 conveyed in an upright position, and the timber unit 999 laid down by the laying device 62 in the loading direction A second transport conveyor 63 as transport means for transporting, a rotating unit 64 that rotates about an axis that is orthogonal to the transport direction of the second transport conveyor 63 on a horizontal plane, and a rotating unit 64. And a sandwiching portion 65 that sandwiches the laminated material 999 conveyed by the second conveyor 63.

  The 1st conveyance conveyor 61 is comprised by the belt-shaped conveyance belt conveyor, and it mounts and conveys a target object on a conveyor. The placement position of the placed object on the conveyor does not change, and the object is simultaneously transported by the conveyor itself being pulled in a certain direction by a drive unit (not shown).

  The side-down device 62 is located at the front end of the first transport conveyor 61 in the transport direction, supports the side surface of the laminated material unit 999 transported in a standing state, and transports the first transport conveyor 61 in the transport direction. A rotation support portion 621 that rotates about a direction orthogonal to the rotation direction, a pulling-down portion 622 that rotates the rotation support portion 621 in the conveying direction, and the like.

  As shown in FIG. 13, the rotation support portion 621 is substantially L-shaped in side view, and protrudes from a contact surface portion 6211 that contacts the side surface of the laminated material unit 999, and from below the contact surface portion 6211. And a protrusion 6212 that supports the laminated timber unit 999. And if the rotation support part 621 rotates in the state in which the laminated material unit 999 is supported by the protrusion 6212, the laminated material unit 999 is laid down in a state where the side surface of the laminated material unit 999 is in contact with the contact surface part 6211. .

The pulling unit 622 includes, for example, a metal rod 622a and a slide device (shown) having a slide mechanism in which one end of the metal rod 622a is connected above the rotation support portion 621 and the other end is provided in the reversing device 6. (Omitted) etc.
When one end of the metal rod 622a is pulled in a direction away from the rotation support portion 621 by the slide device, the rotation support portion 621 is pulled and rotated in the transport direction side. On the other hand, the rotation support part 621 rotates to the opposite side to the transport direction by returning the slide device to the original position.

  The second conveyor 63 is a device that conveys the laminated material unit 999 laid down by the laying device 62 in the stacking direction. The 2nd conveyance conveyor 63 is comprised by the belt conveyor similarly to the 1st conveyance conveyor 61, and it conveys by mounting an object and moving. In the present embodiment, three second conveyors 63 that convey the horizontally laminated laminated unit 999 in a direction substantially perpendicular to the length direction of the laminated material 900 are provided apart from each other.

  The rotating unit 64 plays a role of rotating the clamping unit 65 in a certain direction. The rotating unit 64 is provided so as to rotate about the direction orthogonal to the transport direction of the second transport conveyor 63 on the horizontal plane. Since the pinching portion 65 is connected to the rotating portion 64, the holding portion 65 performs the same rotating operation by the rotating motion of the rotating portion 64.

The clamping unit 65 functions to sandwich the laminated material unit 999 conveyed by the second conveyance conveyor 63.
The clamping unit 65 is configured by connecting two parallel arms 651 and 651 to the rotating unit 64. It is sufficient that the length of the arm 651 constituting the holding part 65 is substantially the same as or slightly longer than the length in the stacking direction of the laminated unit 999 that can be pressed by the pressing device 5. Further, it is sufficient that the distance between the two parallel arms 651 and 651 is slightly wider than the length in the width direction of the lamina 9 constituting the glulam unit 999.
The sandwiching portion 65 is provided with a first sandwiching portion 65a, a second sandwiching portion 65b, a third sandwiching portion 65c, and a fourth sandwiching portion 65d at intervals of 90 degrees around the rotating portion 64. In the present embodiment, the third clamping part 65c is located on the opposite side of the center of the rotating part 64 of the first clamping part 65a, and the center of the rotating part 64 of the second clamping part 65b is centered. A fourth clamping portion 65d is located on the opposite side of the clamp.
In addition, since the attachment position of the arm 651 is provided between the adjacent second transport conveyors 63, the clamping unit 65 can rotate without being obstructed by the second transport conveyor 63.

  The laminated material unit 999 reversed by the reversing device 6 is conveyed to the cutting device 7 by the second conveying conveyor 63.

  The cutting device 7 is a device for cutting the side surface of the laminated material 900 conveyed from the reversing device 6 to make the side surface of the laminated material 900 smooth to obtain a product size.

  The carry-out device 8 is a device for transporting a plurality of laminated materials 900 and carrying them out from the laminated material manufacturing apparatus 100. The carry-out device 8 has substantially the same configuration as the carry-in device 2, but is different from the carry-in device 2 in that it conveys the laminated material 900 instead of the lamina 9. It is transported in laminated wood units.

  Next, the operation of each device in the manufacturing process of the laminated material 900 of the present embodiment will be described. Here, as shown in FIG. 2B, when the laminated material 900 made of four laminaes is manufactured, the pressing device 5 in a state where the two laminated materials are laminated (the laminated material unit 999), A case where processing by the reversing device 6 is performed will be described as an example.

  When the production of the laminated wood 900 is started, the lamina 9 for producing the laminated wood 900 is carried into the carry-in device 2 of the laminated wood manufacturing apparatus 100 by the coarse material supply unit 1. Here, first, laminas 9a, 9b, 9c, and 9d necessary for manufacturing the first laminated material 901 are carried in. Subsequently, the laminas 9e, 9f, 9g, and 9h necessary for manufacturing the second laminated material 902 are carried in.

  The plurality of laminaes delivered to the carry-in device 2 by the coarse material supply unit 1 are transported in the order of 9a, 9b, 9c,..., 9h and carried into the coating device 3.

  In the application device 3, a honeymoon adhesive is applied to each lamina 9. Specifically, an adhesive as an adhesive constituent material A is applied to the upper surface 92 of the lamina 9 disposed at the middle and lower portions of the laminated members 901 and 902, and the upper and middle portions of the laminated members 901 and 902 are applied. A curing accelerator as the adhesive constituent material B is applied to the bottom surface 91 of the lamina 9 arranged in the above.

Specifically, first, an adhesive is applied to the upper surface 92 of the lamina 9a carried into the application device 3 by the application roller 3211 of the first application part 32A.
Subsequently, the lamina 9a is conveyed to the 2nd application part 32B. In the second application unit 32B, the auxiliary conveyance unit 322 is located in the middle of the conveyance unit 31 and assists the conveyance of the lamina 9a. Therefore, the lamina 9a is conveyed on the auxiliary conveyance unit 322 and is conveyed again. It is mounted on the part 31 (refer FIG. 3). Accordingly, the bottom surface 91 of the lamina 9a is transported to the stacking device 4 in a state where the adhesive is applied only to the upper surface 92 without being applied with the curing accelerator.

Next, the lamina 9b, which is the lamina located at the second level from the bottom of the laminated material 901, is conveyed to the coating device 3. First, an adhesive is applied to the upper surface 92 of the lamina 9b by the first application part 32A. The lamina 9b to which the adhesive has been applied is then conveyed to the second application part 32B.
Here, in the 2nd application part 32B, before the lamina 9b is conveyed to the 2nd application part 32B, by the 2nd moving mechanism part 33B in the 2nd application part 32B, an auxiliary conveyance part. 332 and the application main body 321 are exchanged. FIG. 14 is a top view of the coating apparatus 3 after the second coating unit 32B is moved by the second moving mechanism unit 33B. Specifically, the auxiliary conveyance part 322 and the frame part 332 connected to the application main body 321 are switched in the direction in which the application main body 321 and the auxiliary conveyance part 322 are switched along the rail part 331 (arrow in FIG. 14). By sliding in the direction).
As shown in FIG. 14, since the lamina 9b is conveyed to the second application part 32B and passes through the application main body 321, the application roller 3211 and the bottom surface 91 of the lamina 9b are in contact with each other. The curing accelerator is applied to the bottom surface 91 of the lamina 9b.
Accordingly, the laminator 9b in which the adhesive is applied to the upper surface 92 by the first application unit 32A and the curing accelerator is applied to the bottom surface 91 by the second application unit 32B is stacked by the conveyance unit 31. It is conveyed to the device 4.

  Similarly to the lamina 9b, the lamina 9c is transported to the stacking device 4 by the transport unit 31 with the adhesive applied to the upper surface 92 and the curing accelerator applied to the bottom surface 91.

Next, the lamina 9d is conveyed to the application device 3. Before the lamina 9d is transported to the first coating unit 32A, the auxiliary transport unit 322 and the coating body 321 are replaced by the first moving mechanism unit 33A in the first coating unit 32A. Is called. FIG. 15 is a top view of the application device 3 after the first application unit 32A has been moved by the first movement mechanism unit 33A. Specifically, the auxiliary conveyance unit 322 and the frame portion 332 connected to the application main body 321 are changed in a direction in which the application main body 321 and the auxiliary conveyance unit 322 are switched along the rail portion 331 (in FIG. 15). Swapping is performed by sliding in the direction of the arrow.
As shown in FIG. 15, the lamina 9d is conveyed by the auxiliary conveyance unit 322 located in the middle of the conveyance unit 31 in the first application unit 32A, so that the adhesive is applied to the upper surface 92 of the lamina 9d. No attachment is made. In the 2nd application part 32B, in order to pass through the application main body 321 located in the middle of the conveyance part 31, a hardening accelerator is applied to the bottom face 91 of the lamina 9d. That is, the lamina 9d is coated with the curing accelerator only on the bottom surface 92. Then, the lamina 9d is transported to the stacking device 4 by the transport unit 31.

  An adhesive and a curing accelerator are applied to the laminas 9e to 9h forming the second laminated material 902 by the same method. That is, the lamina 9e is coated with an adhesive by the coating device 3 (see FIG. 3) having the same configuration as the lamina 9a, and the lamina 9f and 9g are applied with the same configuration as the lamina 9b and 9c. 3 (see FIG. 14), the adhesive and the curing accelerator are applied, and the lamina 9h is applied with the curing accelerator by the application device 3 (see FIG. 15) having the same configuration as the lamina 9d. .

Each lamina is then conveyed to the stacking device 4.
In the stacking device 4, each lamina is stacked in the order of conveyance. In other words, 9a is positioned at the lowest level, 9b is positioned above it, lamina is subsequently stacked, and the stacking is performed in the order in which 9h is positioned at the uppermost level.
Specifically, the lamina 9a is disposed with the upper surface, which is the surface to be bonded, on which the adhesive is applied to the cradle 44 facing upward. Thereafter, the retracting mechanism 43 is operated to cause the lowermost holding member 42 to protrude from the alignment surface 40A, and the lamina 9b coated with an adhesive is disposed on the holding member 42. In this state, the upper holding member 42 remains immersed from the alignment surface 40A, and does not interfere with the operation of placing the lamina 9b on the lowermost holding member 42. Similarly, the holding member 42 in the second step from the bottom is projected from the alignment surface 40A by the retracting mechanism 43, and the lamina 9c coated with an adhesive is disposed on the holding member 42. This operation is repeated until the lamina 9h is held by the uppermost holding member 42.

  When the lamina 9h is held up to the uppermost holding member 42, the retracting mechanism 43 is operated, and all the holding members 42 are pulled out almost simultaneously (subtracted from the alignment surface 40A). Here, pulling out substantially simultaneously includes not only the case where the holding members 42 are pulled out in exact synchronization, but also the case where the holding time of the holding members 42 is slightly shifted. For example, the case where the holding member 42 is pulled out in order from the uppermost holding member 42 to the lowermost holding member 42 is included. In this case, the uppermost holding member 42 is pulled out so that the uppermost lamina 9h becomes the second step. Immediately after being dropped onto the lamina 9g held by the holding member 42, the second holding member 42 may be pulled out, and this may be repeated up to the lowermost holding member 42. Then, since the plurality of laminas 9 are restricted from moving in the horizontal direction by the alignment surface 40A, they fall downward along the alignment surface 40A and are superimposed on the cradle 44 instantaneously (substantially simultaneously). In the case where the holding member 42 is pulled out in order from the top, the distance that each lamina 9 moves is shortened, and the lateral displacement of the lamina 9 is reduced.

In the stacking device 4, a lamina 9a having an adhesive applied to the upper surface is placed at the lowest level, an adhesive is applied to the upper surface, and a laminator having a curing accelerator applied to the bottom. 9b and 9c are placed, and further, a lamina 9d having a bottom surface coated with a curing accelerator is placed thereon.
Further, above lamina 9d, lamina 9e having an adhesive applied to the top surface, lamina 9f and 9g having an adhesive applied to the top surface and a curing accelerator applied to the bottom surface, and a curing accelerator on the bottom surface. Lamina 9h coated with is sequentially stacked.
That is, the second laminated material 902 is stacked above the first laminated material 901, that is, in the state of the laminated material unit 999, and is conveyed to the press device 5.
Two stacking devices 4 are provided in parallel (not shown), and the lamina 9 stacked by each stacking device 4 passes through two conveying paths 57 provided corresponding to each. Then, it is conveyed to the press device 5.

  Next, the stacked lamina 9 is pressed in the horizontal direction and the vertical direction by the pressing device 5. First, the side cylinder device 522 is advanced toward the pressure-resistant wall 55 to press the plurality of laminas 9 in the horizontal direction. Thereby, the side surfaces of the plurality of laminas 9 are aligned. Thereafter, the piston rod 5121 of the cylinder device 512 is lowered, and the plurality of laminas 9 are pressed in the loading direction.

  Specifically, when the electrical signal information acquired by the detection sensor 53 that detects the length of the lamina 9 that is carried in is input to the control unit 54, the CPU 541 reads the press unit control program 5431 and the side surface read from the ROM 543. The press unit control program 5432 is expanded in the RAM 542 and executed based on the input electric signal information. Then, it is determined which of the plurality of cylinder devices 512 and the side cylinder device 522 is to be operated, and each instruction is output to the cylinder device and the side cylinder device to perform the press. Is called.

  Hereinafter, the detection information input to the control unit 54 when the detection sensor 53 detects the lamina 9 is “1”, and the detection information input to the control unit 54 when the lamina 9 is not detected is “0”. ". In addition, a case where a lamina 9 having a length that is approximately half the length of the press device 5 in the x direction is carried in will be described as an example.

When the lamina 9 is carried in, the detection sensors 53 a to 53 d input “1” to the control unit, and the detection sensors 53 e to 53 h input “0” to the control unit 54. Then, the control unit 54 determines that the end portion of the lamina in the longitudinal direction is located between the side columns 523d and 523e, and inputs a drive signal to the cylinder devices 512a to 512g and the side cylinder devices 522a to 522d. In accordance with this instruction, the cylinder devices 512a to 512g and the side cylinder devices 522a to 522d apply pressure to the press plate 511 and the side press plate 512 to perform pressing.
At this time, the cylinder devices 512h to 512m that did not receive a drive signal are connected to other cylinder devices via the press plate 511, and thus move downward in conjunction with the movement of the press plate 511. The cylinder device does not apply pressure to the press plate 511. Similarly, the side cylinder devices 522e to 522h to which no drive signal is input also move inward in conjunction with the movement of the side press plate 521.

That is, when the information about the presence or absence of the lamina 9 at each point (that is, the length of the lamina) detected by the detection sensor 53 is input to the control unit 54, the length of the lamina 9 carried in is pressed. Only the sufficient cylinder device and the side cylinder device operate and press is performed.
The plurality of laminaes pressed by the press device 5 are placed on the first laminated material 901 formed by the laminas 9a to 9d, and the second laminated material 902 formed by the laminas 9e to 9h is placed. In addition, the laminated material unit 999 is carried into the reversing device 6.

  The laminated lumber unit 999 is placed on the first conveyor 61 with the stacking direction as the z direction. Then, when the laminated material unit 999 is conveyed to the rotation support portion 621 (FIG. 13A), one end of the metal bar 622a connected to the rotation support portion 621 is rotated by a slide device (not shown). It is pulled away from the moving support portion 621. Along with this, the rotation support unit 621 is pulled to the downstream side in the conveyance direction of the laminated material unit (FIG. 13B), and the laminated material unit 999 placed on the rotation support unit 621 is at the same time of the laminated material unit 999. It is laid sideways with the loading surface as the bottom surface (FIG. 13C). The laminated material unit 999 is placed on the second conveying conveyor 63 in such a direction that the second laminated material 902 is located in front of the first laminated material 901, that is, upstream in the laminated material unit conveying direction. When the placed laminated unit 999 is conveyed by the second conveyor 63, one end of the metal bar 622a is moved in the direction of the rotation support portion 621 by the slide device (not shown), thereby supporting the rotation. The part 621 returns to the original position (FIG. 13D).

Next, the laminated material unit 999 is conveyed to the rotating unit 64 by the second conveyor 63. At this time, the two arms 651 and 651 that form any one of the clamping parts 65 (the first clamping part 65a in the present embodiment) of the clamping parts 65 provided in the rotating part 64 are the first ones. The laminated material unit 999 is conveyed while being held at a position substantially parallel to the conveying belt surface of the second conveying conveyor 63 (see FIG. 12). Then, the laminated lumber unit 999 is inserted between the two arms 651 and 651, and is disposed at a position where the first clamping portion 65a can be sandwiched.
Next, the rotating unit 64 is driven by a driving unit (not shown) and rotates in the conveying direction of the laminated material unit 999 (left direction in FIG. 12). Then, with the rotation of the rotating unit 64, the clamping unit 65 also rotates in the same direction, and the laminated material unit 999 is lifted from the second transport conveyor 63 by the first clamping unit 65a, and leftward about the rotating unit 64 Move to draw a semicircle.
At this time, each laminated material forming the laminated material unit 999 is configured such that the second laminated material 902 is located in front of the laminated material unit transport direction, and the first laminated material 901 is located behind.
The rotation unit 64 rotates 180 degrees, and the first clamping unit 65a is positioned so that the arms 651 and 651 of the first clamping unit 65a and the conveyance belt surface of the second conveyance conveyor 63 are substantially parallel (FIG. 12). The position of the third clamping portion 65c), the rotating portion 64 temporarily stops rotating. At the same time, the laminated material unit 999 is placed on the upper surface of the belt of the second conveyor 63.
At this time, each laminated material forming the laminated material unit 999 is configured such that the first laminated material 901 is located in front of the laminated material unit transport direction, and the second laminated material 902 is located behind.

  Next, the first laminated material 901 and the second laminated material 902 are carried into the cutting device 7. In the cutting device 7, the side surfaces of each laminated material are cut so as to have product dimensions.

  Next, the first laminated material 901 and the second laminated material 902 are carried out from the laminated material manufacturing apparatus 100 to the outside (for example, a member storage unit) by the carry-out device 8.

  According to the laminated wood manufacturing apparatus 100 described above, the lamina 9 transported by the transport unit 31 of the coating device 3 that applies the adhesive to the lamina 9 is coated with the adhesive by the coating unit 32. The application unit 32 can be moved in the horizontal direction by the movement mechanism unit 33. Thereby, with respect to the lamina 9 to which the adhesive is not applied, the adhesive is not applied by moving the application portion 32 in the horizontal direction by the moving mechanism portion 33, and the lamina 9 is selectively applied. An adhesive can be applied to the adherend surface. That is, the lamina 9 to which the adhesive is applied and the lamina 9 to which the adhesive is not applied can be conveyed on the same conveyance line. Accordingly, it is possible to efficiently apply the adhesive with one continuous conveyance line.

In addition, the application part 32 moves only by sliding the frame part 332 in the horizontal direction along the rail part 33. Thereby, the application part 32 can be moved easily and reliably, and selective application | coating of an adhesive agent can be performed easily and reliably.
Further, since the application unit 32 includes the application main body 321 and the auxiliary conveyance unit 322, the lamina 9 delivered from the conveyance unit 31 is conveyed by either the application main body 321 or the auxiliary conveyance unit 322. Will be. Thereby, even when application | coating of an adhesive agent is not performed, the lamina 9 will be conveyed reliably by being conveyed on the auxiliary conveyance part 322. FIG.

  And, the application device 3 is provided with a first application part 32A and a second application part 32B, and each application part 32A, 32B is independently movable in the horizontal direction, Not only can two different types of adhesive constituent materials be applied, but also whether or not two types of adhesive constituent materials are applied can be independently determined without being affected by each other. Thereby, not only can an efficient bonding process be performed using two types of adhesive component materials, but also the first transfer mechanism 33A and the second transfer mechanism 33B can apply each of them. Since the main body can move independently, it is possible to prevent useless application of the adhesive.

An adhesive and a curing accelerator can be used as the two types of adhesive constituent materials. As a result, the adhesive can be cured in a short time, and the laminated material can be produced in a shorter time.
Furthermore, the adhesive and the curing accelerator are applied to different surfaces. Thereby, the hardening acceleration of the adhesive by the hardening accelerator is started only after the bonded surfaces of the lamina are bonded to each other, and the bonding and fixing of the lamina can be made stronger.

  And since the said coating apparatus 3 is used for the laminated material manufacturing apparatus 100, the time concerning laminated material manufacture can be shortened and a laminated material can be manufactured efficiently.

  In the above description, in order to explain in order, in the coating apparatus 3, the next lamina 9 is transported when the application of each adhesive constituent material to each lamina 9 is completed. If it is the timing at which each adhesive constituent material is reliably applied to each lamina 9, the conveyance speed can be set as appropriate.

  In the press device 5, the detection sensor 53 is provided corresponding to the side cylinder device 522. However, the detection sensor 53 is not limited to this, and may be provided corresponding to the cylinder device 512. It is good also as providing in a place.

In the reversing device 6, the temporary rotation is stopped when the arms 651 and 651 of the first clamping unit 65 a are substantially in equilibrium with the second transport conveyor 63. As long as the rotation of the rotating unit 64 is not hindered by the clamping unit 65, the rotation may be continuously performed without stopping the rotation.
Further, when the first sandwiching portion 65a rotates 90 degrees, the second laminated portion 65b sandwiches the next laminated material unit 999, and when the first sandwiching portion 65a rotates 180 degrees, The next laminated material unit 999 may be further pinched by the three clamping portions 65c, and the reversing process of the laminated material unit 999 may be performed continuously and efficiently.

It is a figure which shows the principal part structure of the laminated material manufacturing apparatus illustrated as suitable embodiment to which this invention is applied. It is a perspective view of a laminated material. It is a top view of a coating device. FIG. 4 is an enlarged top view of the vicinity of a first application unit and a first movement mechanism unit in FIG. 3. FIG. 5 is a front view of FIG. 4. It is a side view of a loading apparatus. It is a top view of a press apparatus. FIG. 8 is a side view of FIG. 7. It is sectional drawing in the AA 'line of FIG. It is a block diagram which shows schematic structure of a control part and a side surface control part. It is a top view of a reversing device. It is a side view of FIG. It is a side view of a lying apparatus. It is a top view of the coating device after the 2nd application part moved by the 2nd moving mechanism part in FIG. It is a top view of the coating device after the 1st coating part moved by the 1st moving mechanism part in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Coarse material supply part 2 Carry-in apparatus 3 Application | coating apparatus 31 Conveyance part 32 Application | coating part 32A 1st application part 32B 2nd application part 321 Application | coating main body 3211 Application roller 3212 Support roller 322 Auxiliary conveyance part 33 Movement Mechanism (moving means)
33A First moving mechanism (moving means)
33B Second moving mechanism (moving means)
331 Rail portion 332 Frame portion 4 Stacking device 5 Press device 6 Reversing device 7 Cutting device 8 Unloading device 9, 9a, 9b, 9c, 9d, 9e, 9f, 9g, 9h Lamina 91 Bottom surface 92 Top surface 93 Side surface 100 Glulam production Apparatus 900 Glue 901 First Glue 902 Second Glue 999 Glue Unit

Claims (7)

In a coating apparatus for applying an adhesive to the bonded surface of the lamina of a laminated material in which a plurality of laminaes are stacked and bonded,
A transport unit for transporting the lamina;
A coating unit that applies an adhesive to the adherend surface of the lamina transported by the transport unit;
Moving means for moving the application part horizontally;
A coating apparatus comprising: The application device according to claim 1,
The moving means is
A rail portion extending in a horizontal direction so as to be separated from the transport portion;
A frame part slidably provided on the rail part and connected to the application part;
A coating apparatus comprising: In the applicator according to claim 1 or 2,
The application part is
A coating body provided with a predetermined coating means, provided so as to be located in the middle of the transport section at the time of coating;
When the coating main body is detached from the transport unit, the auxiliary transport unit that assists in transporting the lamina is located in the middle of the transport unit, replacing the coating main body,
A coating apparatus comprising: In a coating apparatus for applying an adhesive to the bonded surface of the lamina of a laminated material in which a plurality of laminaes are stacked and bonded,
A transport unit for transporting the lamina;
A first application unit for applying an adhesive to the surface to be bonded of the lamina conveyed by the conveyance unit;
A second application unit that is provided on the downstream side of the first application unit and applies an adhesive to the adherend surface of the lamina conveyed by the conveyance unit;
Moving means for individually moving the first application part and the second application part in the horizontal direction;
A coating apparatus comprising: The application device according to claim 4,
By either one of the first application part and the second application part, an adhesive is applied to the adherend surface of the lamina,
A coating accelerator characterized in that a curing accelerator is applied to the adherend surface of the lamina by the other application part different from the one application part. The application device according to claim 5,
The lamina adherend surface to which application is performed by the first application portion and the lamina adherend surface to which application is performed by the second application portion are different surfaces. Application equipment. It is provided with the application device according to any one of claims 1 to 6,
A laminated material manufacturing apparatus for manufacturing a laminated material by using a lamina coated with an adhesive by the coating device.

Images