WO2007025707A1

WO2007025707A1 - Method and device for producing corrugated-board-like composite material

Info

Publication number: WO2007025707A1
Application number: PCT/EP2006/008424
Authority: WO
Inventors: Rainer Kehrle
Original assignee: Rainer Kehrle
Priority date: 2005-08-29
Filing date: 2006-08-29
Publication date: 2007-03-08
Also published as: DE102005041327A1

Abstract

A description is given of a method for the virtually continuous production of corrugated-board-like composite material from a web of initial product (34). The web of initial product (34) has a planar base web (36) and a corrugated web (38) attached to the base web (36). Divided into strips, the web of initial product (34) is joined together to form the composite material. In this case, the strips are completely coated by means of a coating medium (50). The strips are adhesively bonded by means of an adhesive medium to form a composite material, the adhesive medium and the coating medium (50) being the same.

Description

description

Method and device for producing corrugated cardboard

composite material

Field of application and state of the art

The invention relates to a method and an apparatus for the quasi-continuous production of corrugated cardboard-like composite material from a precursor web. The precursor web essentially has a flat base web and a corrugated, wave-like or honeycomb-shaped structure and secured to the base web. The precursor web is divided into strips and assembled into the composite.

Such a method and such a device are known for example from GB 1 395 801. It describes a device by means of which a composite material is produced from a precursor web, which essentially consists of a flat base web and a corrugated wave web, wherein the corrugated web is fastened to the base web. For this purpose, the precursor web is cut into strips of equal width and then joined together by gluing to form a composite material plate. A coating of the composite material is not provided.

Furthermore, EP 0 183 393 A2 discloses a sheet-like and corrugated cardboard-like composite material in which a substantially straight base sheet and / or a corrugated wave sheet is provided in sections with a coating. A coating of the entire composite material is not provided, so that the composite material may have locations that are not protected, for example, against external influences. Task and solution

It is an object of the invention to provide a method and an apparatus for the quasi-continuous production of corrugated cardboard-like composite material, by means of which corrugated cardboard-like composite material with comprehensive properties can be easily produced.

This object is achieved by a method having the features of claims 1 and 7 and by a device having the features of claim 11 and a corrugated cardboard-like composite material having the features of claim 19. Advantageous and preferred embodiments of the invention are the subject of further claims explained in more detail below. The wording of the claims is incorporated herein by express reference. Some of the following, but not exhaustive, features and properties apply to the process as well as to the device and composite material. They are described in part only once, but apply independently to both the method and the device. Furthermore, the order of the listed features is not binding but rather may be changed according to an optimized method or apparatus for the optimized method.

According to the invention, the method comprises the steps of completely coating the precursor web, the strip or the composite material and bonding the strips to form a composite material. The coating is carried out with a coating medium. The gluing of the strips is done with an adhesive medium, wherein the adhesive medium belongs to the same class of material as the coating medium or adhesive medium and coating medium are the same. The precursor web can be made of, for example, a metal, paperboard or paper, a composite material or the like, as well as a combination of these materials. The wave path can be glued, soldered, welded or fixed by means of another type of connection on the base web, for example. The waves of the wave path can be symmetrical or asymmetrical. They may have a round shape, for example a sinusoidal shape, an angular shape, for example a triangular or polygonal shape, or a mixed shape, for example a semicircular arc, which is followed by a straight transverse web. However, the heights of the waves are always at least approximately identical within a precursor web type.

The precursor web is preferably present as a roll, so that it is present as a quasi-endless raw material. However, it is also possible and extremely advantageous, for example, when using metallic precursor webs, to join the precursor webs just prior to the production of the corrugated cardboard-like composite material from the base web and the web.

As a honeycomb or honeycomb-like training is understood here a volume which is at least approximately completely enclosed on its lateral surface by a material bounding the honeycomb.

By means of the complete coating according to the invention of the precursor web, of the strip or of the composite material agent with a coating medium, it is achieved that the coating is applied without gaps at all points of the composite material. This has the effect that, for example, a complete protective effect is ensured by the coating used. Such a protective effect can be, for example, a flame-retardant, water-repellent and / or a herbicidal or fungicidal action, whereby also , _

Protective effects are conceivable, which are known for example from climate membranes. The use of special coating media, for example plastics such as thermoplastics or the like, can further increase the load-bearing capacity of the composite material.

By virtue of the fact that adhesive media and coating media are the same or belong to the same material class, a protective effect of the composite material is also achieved at non-coatable sites, since the base material of the precursor web is completely enclosed by the media. Uncoated regions are, for example, contact surfaces between the base web and the wave web or regions into which the coating medium does not penetrate due to its cohesion.

As the adhesive medium or coating medium, for example, resins or the like can be used. The use of phenols as coating medium or adhesive medium has proven to be particularly advantageous.

In one embodiment of the invention, the strips are first bonded to the composite material with the adhesive medium, and the composite material is subsequently completely coated with the coating medium. However, it is also possible to completely coat the precursor web or strips first with the coating medium and then bond the strips to the composite material with the adhesive medium. The order to be used depends on the adhesive medium or coating medium used and the effects desired by the coating.

In a further embodiment of the invention, the precursor web with the adhesive medium is used to produce adhesive contact surfaces. , ,

glue the strips together at least partially coated. The adhesive medium can be applied, for example, by means of a spray device, a dip bath, a curtain, rolls or rollers or the like. In this case, devices have proved to be particularly advantageous which permit the application of defined quantities of adhesive medium on defined areas or in defined areas, such as the application of the adhesive medium by means of rollers or rollers only on wave crests of the wave path.

In a further embodiment of the invention, the adhesive medium and the coating medium are cured in a curing distance. The curing within the Aushärtestrecke can be done inter alia by means of tempering, ie elevated temperature. However, the curing can also be effected by means of pressure changes relative to the normal ambient pressure, ie pressure increase or vacuuming, or by means of radiation, for example by means of UV light or IR light or radioactive radiation. Finally, a distance of a certain length may be provided within the manufacturing device, to overcome the composite material requires a certain amount of time. This length of the route is then to be chosen so that the media can crystallize, for example. The curing line is advantageous because the composite material can be further processed directly after curing without slippage of the strips relative to each other and the media can not be stripped off.

In a further embodiment of the invention, a partially cured adhesive medium and / or coating medium is transferred to a tacky state in a release route again. This allows preprocessed webs already pre-coated, which for example can already be delivered or stored as pre-coated precursor web rolls, to be processed into the composite material without the need for a separate coating device or apparatus ,

to apply one of the media must be present. For example, the presence of an explosion-proof room becomes superfluous because, for example, solvent vapors can not be released in the amounts that create an explosive mixture with the air.

In a further embodiment of the invention, the adhesive medium and / or the coating medium is converted by means of heat, solvent action and / or light again in an adhesive state. The emission to be used depends on the respective medium and must take place opposite to the curing effect of the media. When solving the media, it must be ensured that only a small area is dissolved to a certain depth of the corresponding medium, advantageously at least only up to a stage of the media in which they are not yet flowable. Devices for generating the effects may be, for example, IR lamps, UV lamps, radiant heaters, fan heaters, devices for emitting gases, spray nozzles, rollers or the like.

The object underlying the invention is further achieved by a method comprising the steps of completely coating the precursor web, the strip or the composite material, bonding the strips to a composite material and filling open corrugated cardboard honeycomb. In this case, the precursor web, the strips or the composite material are coated with a coating medium and the strips are glued by means of an adhesive medium. The adhesive medium, the filling medium and / or the coating medium belong to the same material class and / or are the same. By filling the corrugated cardboard honeycomb several effects can be achieved. For example, the composite material can be provided with a higher stability. Also, by means of filling, insulating properties of the composite material can be increased. Filling medium, adhesive and / or coating medium may, for example, be resins or the like, for example phenols. However, it is also possible to use plastics for these media, for example polyurethane (PU) or polystyrene (PS).

In a further embodiment of the invention, the base web and / or the wave path are provided with recesses, by means of which the filling medium is uniformly distributed in the composite material and connect the individual Füllmediumportionen in the individual Wellpappewaben. The base web and / or the wave path can also have recesses which are only recesses with a bottom, or else both through recesses and floor-limited recesses. The filler material forms through the recesses undercuts or bridges between the corrugated honeycomb, so that the filling medium is held not only adhesively but also positively in the composite material. The distribution of the filling material in the composite material becomes more uniform and the stability of the composite material is further improved, for example, according to the principle of reinforced concrete.

In a further embodiment of the invention, the filling medium on fire protection properties and / or other protective properties. The protective properties preferably correspond to those described above with respect to the adhesive medium or coating medium.

In a further embodiment of the invention, a cover layer with the coated, bonded and / or filled composite material is bonded to the filling medium in the corrugated cardboard honeycomb. For this purpose, for example, the corrugated cardboard honeycomb can be overfilled with filling medium, so that the filling medium protrudes slightly beyond the composite material. Before the filling medium has cured, the cover layer is applied and with , ,

glued to the filling medium with the filling medium. However, the cover layer may also itself be provided with the filling medium, in which case the composite material should then be applied to the cover layer in such a way that the filling material can extend into the corrugated cardboard wafers and expand, for example by means of flowing or foaming.

The object underlying the invention is also achieved with a device for the quasi-continuous production of corrugated cardboard-like composite material from a precursor web. The precursor web essentially has a flat base web and a corrugated web which is corrugated or wave-shaped and mounted on the base web. The apparatus has a cutting device for dividing the substantially horizontally extending precursor web into strips. The device also has deflection devices, guide devices and / or pressing devices which bring together the horizontally extending strips substantially in a vertical plane one above the other, optionally rotate them, place them on top of one another and thereby bond them with an adhesive medium. The apparatus further comprises a coating line which coats the precursor web, the strips or the composite material. The adhesive medium belongs to the same class of material as the coating medium or adhesive medium and coating medium are the same. By means of the cutting device, the precursor web is preferably to be divided without stripes and without deformation of the precursor web into strips, for which, for example, rotating knives own particular. The deflecting devices, guiding devices and / or pressing devices can be designed as rollers, rollers, strip-shaped guiding devices, rails or plates. The devices for applying the adhesive medium and the coating medium may be, for example, rollers, rollers, spray nozzles, curtain covers, immersion troughs or the like. , ,

The apparatus for the quasi-continuous production of the composite material may further comprise, for example, a curing line, a piecing line, a backfilling section and a device for applying cover devices.

These and other features will become apparent from the claims and from the description and drawings, wherein the individual features in each case alone or more in the form of sub-combinations in an embodiment of the invention and in other fields be realized and advantageous and protectable Represent embodiments for which protection is claimed here. The subdivision of the application into individual sections and subheadings does not limit the general validity of the statements made thereunder.

Brief description of the drawings

Embodiments of the invention are shown schematically in the drawings and are explained in more detail below. In the drawings show:

1 is a side view of an apparatus according to the invention for carrying out the method according to the invention according to a first embodiment,

2 shows a side view of a device according to the invention for carrying out the method according to the invention according to a second embodiment,

FIG. 4 shows a detailed view of a coated precursor web, FIG. 5 shows a detailed view of a composite material with recesses, and FIG. 6 shows a detailed view of a composite material with filled honeycombs. _ _

Detailed description of the drawings

1 schematically shows a device 10 according to the invention for carrying out the method according to the invention for producing corrugated cardboard-like composite material 12. The device 10 has a feeding device (not shown), a cutting device 14 and deflection devices 16, 18, 20 and pressing devices 22. Furthermore, the device 10 has an application device 24, a coating device 26, a cleaning device 28, a cover device 30 and a cutting device 32.

By means of the feed device, a precursor web 34, for example as corrugated cardboard, in any width, for example, supplied by a not shown roller of the cutting device 14. In this case, the precursor web 34 is arranged on the feed device such that a flat base web 36 of the precursor web 34 faces a standing surface of the device 10. At the top of the base sheet 36, a wavy wave path 38 is attached and glued. The cutting device 14 has a rotatable shaft 40 on which a plurality of cutting discs 42 are arranged at equal distances from the respective directly adjacent blade disc. The number of cutting discs 42 is arbitrary. By means of the cutting device 14, the precursor web 34 is divided into equal strips 44 a, 44 b, 44 c, 44 d, 44 e waste-free.

Subsequently, the strips 44 are provided by means of the applicator 24 with an adhesive, wherein the applicator 24 is formed as a rotatably mounted roller. The adhesive is applied only in relatively small areas of wave crests 46 of the wave path 38. The adhesive may be, for example, a phenolic resin. , _

After application of the adhesive, the strips 44 are fed to a rotatably mounted deflection roller 16, from which the strips 44 are deflected to different height levels. To deflect the strips 44, rotatably mounted deflection rollers 18 are used, which are arranged in the course of the device after the deflection roller 16. The pulleys 18 are also arranged at different height levels.

Changing the height levels of the strips is necessary to stack the strips one on top of the other. For this purpose, the strips 44 are combined by means not shown guide rails and the guide rollers 20 so that each form an underside of a base web 36 of a first strip with a wave crest of a wave path 36 of a second strip a contact surface. By means of the deflection rollers 20, the strips 44 are aligned such that their outer edges are aligned.

By means of pressing devices 22, the stacked strips 44 are pressed together, so that the adhesive between the strip is subjected to a pressure. Subsequently, the resulting composite material 12 is provided with a cover layer 48 by means of a cover device 30. This is supplied to the strand 12 by a roll, not shown. The composite material 12 may have any height and width. The height and width of the composite material shown in the drawings is merely exemplary. The same applies to the number of strips 44.

The coating device 26 with the spray nozzles applies a coating medium 50, for example a phenolic resin, to the composite material 12. The coating medium and the adhesive medium preferably belong to the same material class or are identical. Designed as air nozzles cleaning devices 28 remove too much _.

applied coating medium 50 from the honeycomb of the composite material 12 by means of compressed air.

Subsequent to the coating device 26 and the cleaning device 28, a curing line 52 shown as a dashed square is provided. Within the curing device 52, the coating medium 50 and the adhesive medium are cured. This can be done for example by means not shown heaters or IR lamps or UV lamps.

Finally, the composite material 12 is cut into composite sheets by means of the cutter 32. The cutting device 32 is preferably designed as a rotating knife whose cutting movement is synchronized according to arrow 52 during a feed movement of the strand 12 according to arrow 54. This results in a relative movement of the cutting device 32 to the strand 12, which runs parallel to the arrow 52, whereby a straight cut is formed.

In contrast to FIG. 1, the device 10 according to FIG. 2 has, in addition to the cover device 30, a further cover device 56. By means of the second cover device 30, which supplies a cover layer 58 to the strand, the honeycomb-like chambers of the strand 12 are covered. The cover layer 58 is connected to the strand 12, preferably glued.

Another difference between the embodiment according to FIG. 2 and that according to FIG. 1 is that the device 10 has no separate application and coating devices and no cleaning device. Rather, a combined application and coating device 60 is provided, by means of which the coating medium 50, which is also used as an adhesive medium, is applied to the strips 44a, 44b, 44c, 44d, 44e and which is shown here schematically as an immersion bath. By _ _

the dipping baths are passed through the strips 44a, 44b, 44c, 44d, 44e, so that the coating medium 50 can wash around all areas of the strips 44a, 44b, 44c, 44d, 44e. As will be described with reference to a later figure, the coating medium 50 used as the adhesive medium may be used as a filler for the composite material as needed.

Instead of the combined application and coating device 60, it is also possible to provide a release path 60 ', in which a coating medium, with which the precursor web 12 is already precoated, is again converted into an adhesive-capable state. The transfer can be effected for example by means of a solvent 50 'or by means not shown heating or light devices.

3 shows a detailed view of a composite material plate. Therein, the base webs 36, the wave paths 38 and the wave peaks 64 and troughs 66 of the wave paths 38 can be seen. The wave peaks 64 form contact surfaces 68 with the base webs 36, in which the strips are glued together. The wave shape of the wave paths 38 creates a honeycomb structure with a multiplicity of honeycombs 62.

In order to glue the individual strips together, more adhesive is applied to the wave crests 64 than is actually necessary for bonding. When assembling the individual strips and applying pressure to the plate strands, the excess adhesive is displaced to the side of the peaks 64 and forms accumulations 70. These accumulations 70 fill an area between the crests 64 and the base tracks 36, in which, for example cohesion of the coating medium, no coating medium could penetrate. In addition, the adhesive contributes to the increased stability of the composite material. , ,

FIG. 4 shows a section of a precursor web 34, which has the base web 36 and the wave web 38. Both the base web 36 and the wave web 38 are completely precoated with the coating medium 50. The coating of the composite preferably has the same configuration as that of the precursor web 34, then only a plurality of strips 44a, 44b, 44c, 44d, 44e are stacked on top of each other.

In contrast to that according to FIG. 3, the composite material 12 shown in FIG. 5 has a plurality of recesses 74, 75, wherein the recesses 74 are provided on the wave flanks 76 of the wave track 38 and the recesses 75 are provided in the base track 36. The recesses 74, 75 can be generated, for example, before the wave path 38 is arranged and fixed on the base web 36. This can be done for example by means of a punching process. The recesses 74, 75 may be distributed regularly and ordered but also disordered in the base web 36, in the wave path 38 or in the composite material 12.

The recesses 74, 75 have the task of connecting the honeycomb 60 with each other, so that a filling medium 76, which is introduced into the honeycomb 60, in the recesses 74, 75 may extend, so that compounds of the individual Füllmediumportionen in the individual honeycombs arise. As shown in Figure 6, a composite material 12 is produced by means of the introduced into the honeycomb filling medium 76, the stability is improved by the not visible in Figure 6 recesses on the principle of reinforced concrete. However, the filling medium 76 in the honeycomb can also be used to transfer its insulating properties, for example, to the composite material 12, which then serves as a carrier structure for the filling medium 76.

Claims

claims

A process for the quasi-continuous production of corrugated cardboard-like composite material (12) from a precursor web (34), wherein the precursor web (34) substantially a planar base web (36) and a corrugated, wave-like or honeycomb structure having and on the base web (36) has a fixed wave path (38) and the precursor web (36) is divided into strips (44) and joined together to form the composite material (12), comprising the steps of:

Completely coating the precursor web (34), the strip (44) or the composite material (12) with a coating medium (50),

Adhering the strips (44) to a composite material (12) with an adhesive medium, the adhesive medium belonging to the same class of material as the coating medium (50) or adhesive medium and coating medium (50) are the same.

2. The method according to claim 1, characterized in that the strips (44) are first bonded to the adhesive medium to the composite material (12) and the composite material (12) is then completely coated with the coating medium (50).

A method according to claim 1, characterized in that the precursor web (34) or the strips (44) are first completely coated with the coating medium (50) and the strips (44) are subsequently bonded to the composite material (12) with the adhesive medium. be glued. _ _

4. The method according to any one of the preceding claims, characterized in that the precursor web (44) with the adhesive medium for producing adhesive contact surfaces (68) for bonding the strips (44) is at least partially coated with each other.

5. The method according to any one of the preceding claims, characterized in that the adhesive medium and the coating medium (50) are cured in a Aushärtestrecke (52).

6. The method according to claim 1, characterized in that a partially cured adhesive medium and / or coating medium (50) in a release path (60 ') is again converted into an adhesive state, wherein preferably the adhesive medium and / or the coating medium (50 ) is converted by means of heat, solvent and / or exposure to light again in a tacky state.

7. A process for the quasi-continuous production of corrugated cardboard-like composite material (12) from a precursor web (34), wherein the precursor web (34) substantially a flat base web (36) and a corrugated, wave-like or honeycomb-like structure having and on the base web (34) has a fixed corrugated web (36) or a honeycomb core structure and the precursor web (34) is divided into strips (44) and joined together to form the composite material (12), comprising the steps of:

Adhering the strips (44) to a composite material (12) by means of an adhesive medium,

, ,

Filling open corrugated cardboard honeycombs (60) with a filling medium (76), the adhesive medium, the filling medium (76) and / or the coating medium (50) belonging to the same material class or adhesive medium, filling medium (76) and / or coating medium (50) are the same.

8. The method according to claim 7, characterized in that the base web (36) and / or the wave path (38) with recesses (74, 75) are provided by means of the filling medium (76) evenly distributed in the composite material (12) and the filling medium portions in the individual corrugated cardboard honeycomb (60) are connected.

9. The method according to any one of claims 7 or 8, characterized in that the filling medium (76) fire protection properties and / or further protective properties.

10. The method according to any one of claims 7 to 9, characterized in that with the filling medium (76) in the corrugated cardboard honeycomb (60) a cover layer (48, 58) with the coated, bonded and / or filled composite material (12) is glued.

11. An apparatus for the quasi-continuous production of corrugated cardboard-like composite material (12) from a precursor web (34), wherein the precursor web (34) substantially a planar base web (36) and a corrugated or wave-like and on the base web (36 ) and the apparatus (10) has a cutting device (14) for dividing the substantially horizontally extending precursor web (34) into strips (44), and wherein the device (10) comprises deflection devices (16 , 18, 20), guide devices and / or pressing devices (22), which are the horizontally extending

,

Strip (44) substantially in a vertical plane merge together, superimpose on one another and thereby bond by means of an adhesive medium, characterized in that the device has a coating path which the precursor web (34), the strips (44) or the composite material ( 12) and that the adhesive medium belongs to the same class of material as the coating medium (50) or adhesive medium and coating medium (50) are the same.

12. The device according to claim 11, characterized in that deflection devices (16, 18, 20), guide devices and / or pressing devices (22), the strips (44) first glued together by means of the adhesive medium and the coating line then the composite material (12) with the Coating medium (50) completely coated.

13. The device according to claim 11, characterized in that first the coating line the precursor web (34) or the strips (44) completely coated with the coating medium (50) and then deflection devices (16, 18, 20), guide devices and / or Pressing devices (22) glue the strips (44) together with the adhesive medium.

14. The device according to one of claims 11 to 13, characterized in that the coating path, the precursor web (34) coated with the adhesive medium at least partially, to produce adhesive contact surfaces (68) for bonding the strips (44) together.

15. Device according to one of claims n to 14, characterized in that the device (10) has a curing path _ _

(52), in which the adhesive medium and the coating medium (50) cure.

16. Device according to one of claims 11 to 15, characterized in that the device (10) has a detachment path (60 '), the partially cured adhesive medium and / or coating medium (50) again converted into a stickable state, preferably the release path (60) converts the adhesive medium and / or the coating medium (50) back into a stickable state by means of heat, solvent action and / or the action of light.

17. Device according to one of claims 11 to 16, characterized in that the device (10) has a disposable path which fills the corrugated cardboard honeycomb (60) with a filling medium (76), wherein the filling medium (76), the adhesive medium and / or the coating medium (50) belong to the same material class or are the same.

18. Device according to claim 17, characterized in that the device (10) has a covering device (30, 58) which engages a covering layer (48, 58) with the coated, bonded and / or filled composite material (12), wherein the filling medium (76) adheres the cover layer (48, 58) to the composite material (12).

19. corrugated composite material (12), characterized in that it is produced by a method and / or a device (10) according to one of the preceding claims.