SE512767C2 - Procedure for joining paper, device and binderless joint - Google Patents

Abstract

A method of joining together at least two paper sheets (1, 2). The method comprises the steps of moistening each paper sheet (1, 2) with a determined amount of water within the region of the intended join (9); placing the paper sheets together with the moistened regions in abutment with one another; and processing the moistened regions of the combined paper sheets in an ultrasound welding device (7, 8) such that at least 80 percent by weight of the water applied will be removed. The invention also relates to apparatus for carrying out the method and to a join produced by means of said method.

Description

In a preferred embodiment, the sheets of paper are calendered before processing in the ultrasonic welding device. Furthermore, the appropriate humidification of the paper sheets is determined empirically by carrying out the procedure with different degrees of humidification of the paper sheets but otherwise under the same conditions, whereby the joint strength is measured for each degree of humidification. Thereafter, the appropriate degree of machining in the ultrasonic welding device is determined empirically by processing sheets of paper with the same degree of humidification with different energy supplies to the ultrasonic welding device, the joint strength being measured for each value of the energy supply.

The invention also relates to a device for carrying out the method and joining together at least two sheets of paper in the form of two running paper webs, which are unrolled from supply rolls, characterized in that the device comprises a humidifying unit, means for joining the paper webs and an ultrasonic welding, said arrangement are arranged one after the other in the running direction, as well as means for feeding the paper webs past the humidifying unit and through the joining means and the ultrasonic welding device.

In a preferred embodiment, the joining means are constituted by a calendering device.

The invention also relates to a binderless joint obtained by the method joining at least two paper webs, which is characterized in that it comprises areas with a greaseproof paper-like structure, which have a thickness of less than 50%, preferably less than 30%, of the total thickness of the paper webs. .

The invention will now be described with reference to the accompanying figures, of which; Fig. 1 schematically shows an embodiment of a device according to the invention for joining paper sheets, Fig. 2 shows a schematic perspective view of a piece of a paper web consisting of two sheets of paper, which are joined together in the device according to Fig. 1, Fig. 3 shows a diagram of the tensile strength and the humidification as a function of the feed speed of the sheets of paper, Fig. 4 shows a diagram of the tensile strength as a function of the ultrasonic pressure for different feed rates and humidifications, and Fig. 5 shows a diagram of the tensile strength as a function of humidity.

The device shown in Figure 1 for joining two paper webs 1,2, which are wound on supply rolls 3,4, comprises a humidifying unit 5, a calendering device 6, an ultrasonic welding unit 7 and a retaining roller 8, which in said order are arranged in succession in the feed direction of the 1.2 paths.

The device works as follows.

When passing the humidifier 5, the paper webs are coated with a certain amount of water. Thereafter, the moistened paper webs 1,2 are passed through a calendering device 6 with the moistened areas abutting each other.

The joined tracks 1,2 then pass through the nip between the ultrasonic horn 7 of the unit 7 and the resistance roller 8.

It has surprisingly been found that after the passage of the ultrasonic welding unit and the resistance roller, the two paper webs are connected to each other within the areas moistened by the unit 5.

Figure 2 shows a perspective view of a cut-out piece of the webs 1,2 after the passage of the ultrasonic welding assembly 7. In the example shown, the resistance roller has rows of projecting projections, which provide rows of connected areas 10 in the resulting joint 9, as shown in Figure 2. In these X nwix mini n 10 15 20 25 30 35 512 767 areas 10, the bonded paper webs are very thin and have a greaseproof paper-like structure.

The strength of the resulting joint depends on the degree of humidification of the paper and on the mechanical energy supplied by the ultrasonic processing. It appears that the joint 9 is for the most part formed by chemical bonds (of which hydrogen bonds probably constitute a predominant part), but mechanical bonds are also likely to occur in the joint. From the greaseproof paper-like structure in the areas 10, it can be concluded that the ultrasonic horn causes a decomposition of the paper fibers within the areas of the abutment roller projections so that areas with short fibers are provided. The presence of water and the heat that arises during the mechanical processing are also necessary conditions for a joint to arise. It is currently not possible to theoretically optimize the degree of humidity and energy supply because it is not really known how the connection between paper webs 1,2 arises. What is known is that in the event of excessive humidification as well as in the event of no humidification, no joint arises during the ultrasonic processing. However, it has been found that a good joint can be achieved at a moisture content of the paper webs as low as 5%, while a humidity of 50% of the webs meant that no joint could be achieved. The humidity of the webs was measured by weighing the weight of the joint area before and after the supply of water and consists of the weight of the supplied water divided by the weight of the paper before the water supply and multiplied by one hundred. The conditions for achieving an optimally strong joint must therefore be determined empirically.

Figures 3 and 4 show how the degree of humidity and energy supply are determined to achieve a maximum strong joint between two paper webs consisting of a paper with a basis weight of 60 g / m2, which has the designation CREPE PAPER WHITE and is manufactured by Arjo Wiggins, Paris, France. These paper webs were passed through a device constructed in accordance with Figure 1. The humidifier was designed so that the passing paper webs were supplied with a certain amount of water per unit time. The calendering pressure was 0.5 bar, which was optimal for this type of paper. The calendering is to facilitate the absorption of water from the surface into the paper.

The ultrasonic welding unit consisted of a unit from Dukane Corp., Illinois, USA with the designation 20A2000. During all experiments, the amplitude of the ultrasonic horn was constant 15 microns.

The energy supply of the ultrasonic welding device was varied by varying its back pressure (UL pressure).

The strength of the resulting joints was measured by SCAN P44: 81.

First, the joint strength and the degree of humidification (g / af) were measured as a function of the feed speed of the paper webs at constant UL pressure. The humidifier delivered a constant amount of water per unit time, which caused the degree of humidification of the papers to decrease with increasing feed rate. The results of these experiments are shown in Figure 3. Curve F refers to the joint strength (N) and curve B refers to the degree of humidification (g / mï.

In a first series of experiments, the paper webs were coated over a width of 0.025 m with 0.82 g of water / min each and the feed speed was increased one step at a time from 5 - 20 m / min.

At each feed rate, the strength of the resulting joint was measured. As shown in Figure 3, the highest joint strength was achieved at the feed speed ll m / min and the degree of humidification 2.98 g / mÄ In a second series of experiments with feed speeds in the range 18 - 30 m / min, the paper webs were coated with 1.66 g water / my. The highest joint strength in this interval was reached at a speed of 22 m / min and a degree of humidity of 3.02 g / m2.

In a third series of experiments with feed speeds in the range 28 - 40 m / min, the paper webs were coated with 2.56 g water / min. The highest joint strength in this interval was achieved at a speed of 31 m / min and a degree of humidity of 3.30 g / mf. In a fourth series of experiments with feed speeds in the range of 38 - 50 m / min, the paper webs were coated. with 3.51 g water / min. Highest joint strength in this interval was reached at a speed of 42 m / min and a degree of humidity of 3.34 g / UF.

From the experimental series shown in Figure 3, it appears that the strength of the resulting joint depends on the degree of humidification.

Figure 4 shows a number of experiments in which the UL pressure, i.e. the back pressure of the ultrasonic horn, was varied while the degree of humidification and feed rate of the paper webs fed through the ultrasonic welding device were kept constant. Curves F and B show, as before, joint strength resp. degree of humidity and the curve UL shows the UL pressure.

As can be seen from Figure 4, a maximum joint strength of more than 7 N was achieved for the feed speeds 11 m / min, 22 m / min and 31 m / min at UL pressures 1.6 bar, 2.4 bar resp. 1.8 bar while for the speed 42 m / min a joint strength of 6 N was achieved at a UL pressure of 3.6 bar. The above-mentioned UL pressure corresponded to resp. feed rate a power of 0.2 kW, 0.217 kW, 0.221 kW and 0.408 kW read on the ultrasonic unit.

From the experiments shown in Figure 4, it thus appears that the joint strength is also dependent on the amount of energy supplied. It thus appears that the energy supplied to the paper webs by the ultrasonic welding unit is of great importance for the joint strength - too little supplied energy and too much supplied energy reduces the joint's strength. There is currently no explanation for this phenomenon, but a possible explanation may be that if too little energy is supplied, the chemical reactions that cause the chemical bonds, which probably account for most of the joint strength, take place too slowly while too much is added. energy causes the reactions to take place too quickly or not at all. It is also possible that some of the bonds formed in the joint are broken during an overly intensive mechanical processing.

From the described experiments it appears that it is relatively easy to empirically determine the conditions which give maximum joint strength. Furthermore, such empirical experiments can also be used to determine the conditions for achieving desired joint strengths, which are less than the maximum joint strength, if, for example, it is desirable to achieve easily opened joints. Thus, by the described method, joints of different strength can be easily produced.

Figure 5 shows two curves I and II over joint strength as a function of the moisture in the joint area of the paper webs.

The feed speed was 30 m / min and for curve I the UL pressure was 1.2 bar and for curve II the UL pressure was 1.8 bar. This figure shows that it is possible to achieve good joints within a relatively wide humidity range.

In carrying out the described method, it has been found to be important that the water supplied to the joint area is largely removed. Thus, no more than 20% by weight of the supplied amount of water must remain in the joint area after the paper webs have passed the ultrasonic welding device.

Furthermore, the thickness of the greaseproof paper-like areas 10 in the joint has been measured and found to be less than 30% of the total thickness of the paper webs included.

The described embodiment of the invention can of course be modified within the scope of the invention. For example, other types of ultrasonic welding assemblies can be used than the assembly specified in the description. The sheets of paper can, of course, be stationary and humidifiers and ultrasonic welding devices can be movable. In addition, other types of humidifiers can be used. Furthermore, the method can be used to join more than two sheets of paper. Paper types other than the type of paper used in the experiments can of course be joined together in accordance with the invention. The invention is therefore to be limited only by the content of the appended claims.

Claims (7)

10 15 20 25 30 35 512 767 A method of joining at least two sheets of paper (1,2), characterized by the following steps; each paper sheet (1,2) is moistened by applying a certain amount of water within the area of the intended joint (9) so that the humidity of the moistened areas after the application of water is between 5-50% by weight, the paper sheets are added together with the moistened areas in abut against each other, and the wetted areas of the combined sheets of paper are processed in an ultrasonic welding device (7,8) so that at least 80% by weight of the supplied water is removed. Method according to claim 1, characterized in that the sheets of paper (1,2) are calendered before processing in the ultrasonic welding device. _ Method according to claim 2, characterized in that suitable wetting of the paper sheets (1,2) is determined empirically by carrying out the method with different degrees of wetting (B) of the paper sheets but otherwise under the same conditions, whereby the joint strength (F) is measured for every degree of humidity. Method according to claim 3, characterized in that the appropriate degree of processing in the ultrasonic welding device (7,8) is determined empirically by processing paper sheets (1,2) with the same degree of humidification (B) with different energy supplies (UL) to the ultrasonic welding device, wherein the joint strength (F) is measured for each value of the energy supply. Device for carrying out the method according to claim 1 and joining together at least two sheets of paper (1,2) in the form of two running paper webs, which are unrolled from pre-rollers (3,4), characterized in that the device comprises a humidifying unit (S) , means (6) for joining the paper webs (1,2) and an ultrasonic welding device (7,8), which in said order are arranged one after the other in the running direction of the paper webs, and means for feeding the paper webs past the humidifier and through the joining means and the ultrasonic welding device. Device according to claim 5, characterized in that the joining means (6) consist of a calendering device. Binder-free joint (9) obtained by the method according to claim 1 joining at least two paper webs (1,2), characterized in that the joint (9) comprises areas (10) with a greaseproof paper-like structure, which have a thickness of less than 50%, preferably less than 30%, of the total thickness of the paper webs.