Apparatus for bonding sheet material

Three paperboard webs are glued to one another with as little expenditure of energy as possible. After leaving the gluing apparatus, the finished sheets cut to size are ready for shipment. The middle paperboard web is passed through between two steel rolls which apply glue homogeneously to both sides of the web. High linear pressure is produced in the region of the generatrices of the steel rolls respectively touching the web. Such pressure is necessary in order that a highly viscous polymeric synthetic or natural adhesive, preferably with a solids content of more than 50%, can be used. No special drying facilities are needed, and the water-soluble glue allows recycling without problems.

This invention relates to a method of adhesively joining several flexible 
webs of material and to apparatus for carrying out this method. 
Methods and apparatus for affixing two or more webs of paperboard together, 
or for coating or backing a sheet of paper or paperboard, have already 
been proposed. In one such process, the adhesive is applied to the surface 
of a web of paperboard by means of two rolls which can be pressed together 
with variable pressure. The layer of glue applied is thicker or thinner 
according to the bearing pressure of the two rolls. The web of paperboard 
provided with a coating of adhesive is then fed with the web glued thereto 
between two rolls. This apparatus makes it possible to apply a very fluid 
adhesive uniformly to the web of paperboard, but not a highly viscous 
adhesive. 
In other previously proposed apparatus, the web of paperboard to be 
provided with a coating of adhesive is passed between two rolls, the lower 
roll being immersed in a vat of glue. Excess adhesive is removed by means 
of a doctor blade from the roll coated with glue. This apparatus has the 
drawback that if the leading edge of the doctor blade is damaged even 
slightly, the glue will no longer be applied homogeneously. 
The above-mentioned two methods and the respective apparatus are suitable 
only for applying adhesive on one side. 
Apparatus has also been proposed for applying adhesive on both sides by 
passing the web of paperboard between two rolls, the lower of which is 
immersed in a vat of glue. In addition, glue is fed between the upper roll 
and the web for applying adhesive to the upper side. This method is also 
suitable only for liquid adhesives having low viscosity. 
It is an object of this invention to provide a method and apparatus for 
applying adhesive homogeneously to one or both sides of a flexible web of 
material, wherein the adhesive applied may be highly viscous. In 
particular, it should be possible to utilize a water-soluble, natural or 
synthetic adhesive substance having a solids content of more than 50%. 
Furthermore, the multilayered, adhesively joined paperboard should be very 
smooth. 
To this end, in the method according to the present invention for 
adhesively joining several flexible webs of material, the web to be coated 
with adhesive is conveyed between two middle rolls having rigid surfaces, 
pressable against one another and set in rotation, and an application of 
glue takes place on at least one of the two sides of the web to be coated 
with adhesive by means of the middle rolls substantially in the region of 
the generatrices, touching the middle web, of the middle rolls having 
rigid surfaces, and the webs of material to be adhesively joined to one 
another are fed through a pressing arrangement. 
In the apparatus according to the present invention, for carrying out the 
foregoing method, there are provided, for applying an adhesive to at least 
one of the two sides of a web of material to be coated with adhesive, two 
middle rolls having rigid surfaces, pressable against one another and 
capable of being set in rotation, and at least one feed means for the 
adhesive and a pressing arrangement for adhesively joining the webs of 
material. 
One advantage of the method and apparatus according to this invention is 
that there is no need for a special drying device for the adhesively 
joined webs of material, so that operation with an optimally low 
expenditure of energy is possible. Furthermore, a very homogeneous 
application of adhesive to both sides of the web of material is achieved 
with this method. Moreover, by using water-soluble adhesive, recycling is 
also possible. The webs of material, adhesively joined to one another and 
cut to size, are ready for shipment upon leaving the bonding installation.

The method and apparatus as illustrated in FIG. 1 will now be described. 
Paperboard webs 4-6 to be adhesively joined to one another are conveyed to 
the bonding apparatus from supply rolls 1-3. The middle web 5, to be 
provided on both sides 7 and 8 with a layer of adhesive, e.g., glue, is 
passed between two steel middle rolls 9 and 10 disposed above and below 
the middle web 5, respectively. Situated one on each side of both steel 
rolls 9 and 10 are two rubber-covered lateral rolls 11, 12 and 13, 14. The 
rolls 9 and 10, driven by a motor (not shown), in turn set the lateral 
rolls 11-14 in rotation. The rolls 10, 11, and 12 rotate clockwise, the 
rolls 9, 13, and 14 counterclockwise. The rolls 10, 13, and 14, situated 
under the middle web 5, are secured to a lever 16 pivotable about an arbor 
15. The lever 16 can be raised or lowered by means of a pistoncylinder 
unit 17 in order to press the two steel rolls 9 and 10 against one another 
while a middle paperboard web 5 is passing through. The glue is applied to 
the middle web 5 by the steel rolls 9 and 10, the glue collecting between 
the upper steel roll 9 and the lateral roll 11 and between the lower steel 
roll 10 and the lateral roll 14. By means of the steel rolls 9 and 10, 
glue is applied uniformly to the middle web of paperboard. The two outer 
webs 4 and 6 to be glued to the middle web 5 are conveyed about upper and 
lower guide rollers 18 and 19, respectively, and between two rolls 20 and 
21, pressed against one another, disposed above and below the middle 
paperboard web 5. Two rubber sheets 25 and 26, led over pressing rolls 20, 
23 and 21, 24, respectively, are provided above and beneath the now 
three-layered paperboard web 22. The three webs are glued to one another 
along the path between the two front pressing rolls 20 and 21 and the rear 
pressing rolls 23 and 24. The rubber sheets 25 and 26 may be pressed 
against the three-layered paperboard web 22 by additional rolls 27-33. 
The glued web 22 is cut into suitable sheets 34 by a diagrammatically 
illustrated cutting device 33. 
The actual glue-applying part of the apparatus is shown in detail in FIG. 
2, with only the front roll support 35 being visible. This support 
consists of an upright 36 with an upper horizontal crossbeam 37 screwed to 
it laterally and a pivotable lower horizontal beam 16. The upper and lower 
lateral rolls 11-14, each provided with a rubber covering 38, are 
connected to the upper and lower crossbeams 37 and 16, respectively, by 
mountings 39, 40, 41, and 42. The axles 43, 44, 45 and 46 of the lateral 
rubber-covered rolls 11-14 pass through mountings 39-42. Attached to the 
upper horizontal cross-beam 37 is a vertical mounting 47 for the two rolls 
9 and 10. The height of the mounting 47 can be adjusted by means of a 
handwheel 48 in that an elongated vertical slot 50 provided on a vertical 
support 49 of the mounting 47 is displaceable under a mounting screw 51. 
The upper steel roll 9 is rigidly connected to the vertical support 49. 
Over the axle 52 of the upper steel roll 9 there is a vertically disposed, 
rectangular mounting part 53 having an elongated slot 54. The axle 55 of 
the lower steel roll 10 is mounted in the lower part of the slot 54. The 
lower steel roll 10 is mounted like a pendulum relative to the upper steel 
roll 9. In operation, the lower horizontal crossbeam 16 is pivoted upward 
by the cylinder-piston unit 17 shown in FIG. 1, so that the axle 55 of the 
lower steel roll 10 slides upward in the elongated slot 54, the lower 
steel roll 10 being pressed against the upper steel roll 9. 
The middle paperboard web 5 to be coated with glue comes in contact with 
the two steel rolls 9 and 10 practically only in the region of two 
generatrices, whereupon a very high linear pressure is produced. Thus, the 
application of glue takes place homogeneously at high pressure. 
In the middle above the two upper lateral rolls 11 and 12 there is a glue 
vat 56 by means of which the glue is distributed uniformly on the upper 
steel roll 9 and collects along the generatrix of contact between the 
upper steel roll 9 and the upper lateral roll 11. The high-viscosity 
adhesive is preferably supplied by means of a geared pump through a 
pipeline having a glue outlet in the middle of the rolls 10 and 14. The 
lateral rolls 11-14 bring about a very homogeneous distribution of the 
adhesive on the two steel rolls 9 and 10. A collecting vat 57 for 
collecting excess adhesive is provided under the two lower lateral rolls 
13 and 14. 
The adhesive used is a polymeric synthetic or natural adhesive having a 
solids content of preferably more than 50%. A dextrin glue is particularly 
suitable for the optimum accomplishment of the tasks imposed. Since this 
glue is highly viscous, the necessary high bearing pressure of the steel 
rolls along substantially only one generatrix is required in order to 
apply the glue homogeneously to the middle paperboard web on both sides 
thereof. Through the use of such a high-viscosity glue with a high solids 
content, drying facilities become superfluous, thus leading to a saving on 
energy. For example, the adhesive is applied at about 25 g./sq.m., at 
least one spot of glue being applied per sq.mm. 
Instead of adhesively joining three paperboard webs of equal thickness, a 
middle web of paperboard might equally well be covered on both sides with 
paper. Furthermore, plastic film or aluminum foil might also be used, in 
which case at least the middle web or the two outer webs would have to be 
of a suitable nature to absorb the water contained in the adhesive. 
The multilayer cardboard made from the three single webs of paperboard, 
being about 1.5-4 mm. thick, is particularly suitable for bookbinding 
purposes. For this application, it is important that the multilayer 
cardboard lie absolutely flat. 
The adhesive used must be water-soluble because of recycling. As a result 
of the high solids content, the three adhesively joined paperboard webs 
are already optimally bonded together after leaving the rolls 20-24 with 
the rubber sheets 25 and 26, so that the sheets 34 cut off by the cutting 
device are ready for shipment. 
For exact purposes of application, it has to be possible to cut the 
cardboard with an accuracy of one-tenth of a millimeter, so that a 
homogeneous gluing of the layers is important for this reason as well. 
The webs of material 4-6 wound on the supply rolls 1-3 exhibit a tendency 
to curl in the direction of rolling after a certain storage time. This 
curling tendency can be eliminated by means of a counter-bending device 58 
as shown in FIG. 4. The middle web 5 to be coated with adhesive is led 
over two cylinders 59 and 60, the spacing between which is preferably 
about equal to their diameter. A third cylinder 61 is pressed against the 
middle web 5 from above, by means of a lever arm 62 secured at a pivot 
point 63, so that a counter-bending pressure is imparted to the middle web 
of material as it runs through the counter-bending device 58. The amount 
of pressure exerted upon the middle web 5 by the cylinder 61 between the 
cylinders 59 and 60 may be greater or less, as need be. The amount of 
counterbending pressure needed will be apparent from the degree of 
flatness of the webs after bonding together. 
As shown in FIG. 5, one of the two steel rolls 9 or 10 might be laterally 
offset so that the plane connecting the two axes of rotation of the rolls 
would not run at right angles to the web 5 of material. By varying the 
lateral displacement of one of the two rolls 9 and/or 10, the metering of 
the glue can be controlled and adapted to the material to be coated. In 
this case, the middle web 5 follows a curved path in the region of the 
rolls 9 and 10. With this offset arrangement of the middle rolls 9 and 10, 
the bearing pressure of the two rolls can be less than with the vertical 
arrangement illustrated in FIGS. 1 and 2, or it may even be dispensed with 
since bearing pressure is likewise produced between the middle web of 
material and the rolls owing to the curved course of the web. 
With the method priniciple described above, just two webs might be 
adhesively joined to one another as well, if so desired, in which case the 
mentioned advantages would likewise be achieved. For this purpose, either 
the upper or the lower adhesive feed would simply be eliminated, and only 
one of the two upper or lower supply rolls 1 or 3 would be needed.