WO2022096277A1

WO2022096277A1 - Delamination device for producing double-sided adhesive tapes

Info

Publication number: WO2022096277A1
Application number: PCT/EP2021/079203
Authority: WO
Inventors: Hubertus Keßelheim; Joachim Lenz; Ulrich Thiel; Massimo BERNADELLI
Original assignee: Lohmann Gmbh & Co. Kg
Priority date: 2020-11-07
Filing date: 2021-10-21
Publication date: 2022-05-12
Also published as: DE102020006970B4; DE102020006970A1

Abstract

The invention relates to a flexible delamination device for delaminating two layers in such a way that two forces are generated which, starting from the parting plane, are directed in opposite directions in such a way that they compress layered composites at the relevant individually provided delamination point in such a way that no parting plane is produced at an unintended point and that complete and residue-free delamination occurs where desired.

Description

Delaminating device for the production of double-sided adhesive tapes

The present invention is a special delaminating device for the production of double-sided adhesive tapes.

Lamination is the joining of several layers of different flat materials such as paper, fabrics or foils using suitable means, i.e. laminating means, to join these materials. Such laminating agents are, for example, adhesives, waxes or lacquers. Lamination can have different purposes: By bringing two layers together, at least one of the two layers can be protected, supported or refined by applying a decoration, lamination can be permanent or just temporary. In the case of adhesive tapes, lamination occurs, among other things, when an adhesive surface is covered with a cover, a so-called release liner, which has the function of protecting the adhesive surface after coating on a carrier material during further processing, i.e. ultimately up to the point of application against dirt or undesired premature sticking. Delamination is then understood to mean the redetachment of one layer from the other, in the case of adhesive tapes specifically the redetachment of the release liner from the adhesive surface either immediately before use or during the manufacturing process of the adhesive tape, as is described in more detail in the following invention.

A force is required to delaminate one layer of material from a second. Depending on the application, different terms are used for this force: In principle, the terms “adhesive force”, “peel force” and “separation force” can be used synonymously and are defined as the force that is required to separate two layers, i.e. in the present case to separate an adhesive surface from a surface applied and protecting it. When delaminating, this force is usually referred to as the “separation force”.

When delaminating a composite material that consists of at least three layers (release liner, adhesive layer, carrier material or layer), the layers can be separated at two levels: between liner and adhesive and between adhesive and carrier material. The latter possibility is undesirable and in order to prevent it, the separation force between the cover and the adhesive is set to be much lower than that between the adhesive and the backing. In this case delamination is relatively simple and the requirements for a corresponding delamination unit are low.

During the delaminating process, it is important to ensure that the two material layers in question are separated cleanly and completely. This separation process depends on a number of factors: the adhesive or the adhesive strength of the adhesive, the viscosity of the adhesive, the nature of the cover, which is often provided with a siliconized layer for better detachment (i.e. in particular the type of cover material and the amount and type of silicone applied), the delaminating speed and the delaminating angle, i.e. the angle at which one layer is peeled off and separated from the other layer.

In the production of double-sided adhesive tapes, however, there can be a 5-layer bond with four parting planes in a certain process step. By design, two of these parting planes have high parting forces and two planes have lower and almost equal parting forces. In order to ensure that, in the case of two parting planes with almost the same parting forces, the parting always and completely takes place in one plane, greater demands are placed on the delaminating device. In order to meet these requirements, the delaminating devices corresponding to the state of the art, also called delaminating units, are designed in such a way that the layers to be separated are always guided over a predetermined web path. As a result, a delaminating angle is specified, which can be variably adjusted in some cases, but is always on the same side of the web to be separated. In the case of the known delaminating devices, clean and complete separation is not always the case, which can lead to increased rejects or even complete failure of the delaminating process. The fact that in known systems delamination can only be done on one side as standard also makes the production process less flexible and therefore also very complex. Decoupling devices in the production of adhesive tapes are known to manufacturers of adhesive tapes from the production processes themselves and corresponding information can also be found in the literature. For example, EP 3 206 873 B1 describes the delaminating or relaminating process in the production of patches for transdermal therapeutic systems, in which it is important to laminate a tension-sensitive film from a first band-shaped carrier to a second band-shaped carrier with such a low stretch to allow the film that the second carrier is not deformed by the film laminated to it. The corresponding delaminating device minimizes the tensile forces required to detach the tension-sensitive film from the first carrier, since the separating forces are concentrated on the detachment or delaminating point due to the deflection of the film. For this purpose, the film delaminating station has at least one sensor that controls the two transport devices as required.

DE 102008 038 595 A1 claims a method for producing an adhesive tape with a double-sided adhesive finish, in the course of which two rigid delaminating devices (delaminating rollers) are provided for the two release liners (auxiliary carrier materials) used in the production process.

None of the delaminating devices known from practice or literature allows a flexible delamination of two layers in such a way that two forces are generated which, starting from the parting plane, are directed in opposite directions in such a way that they compress layer composites at the individually provided delamination point on the one hand that there is no separating plane at an unwanted place and on the other hand the complete and residue-free delamination takes place where it is desired. For better clarification of the delaminating device according to the invention, this is explained in more detail with reference to FIG. The corresponding reference symbols have the following meaning:

1 lay-on roller

2 countershaft, calender shaft (tempered) 3a delaminating roller delaminating direction 1

4a Support roller delaminating direction 1

5a satellite roller delaminating direction 1 aA delaminating direction 1 bB delaminating direction 2

3b delaminating roller delaminating direction 2

4b support roller delaminating direction 2

5b satellite roller delaminating direction 2

I Swivel positions of the delaminating roller

II Swivel positions of the support roller for product A

III Swivel positions of the support roller for product B

IV Swivel positions of the satellite roller

A product delamination direction 1 a release liner delamination direction 1

B product delamination direction 2 b release liner delamination direction 2

The Roman numerals I to IV thus designate the possible positions in which the respective roll(s) can be guided around the reference shaft/roll.

The invention relates to a delaminating device as used in the production of adhesive tapes. This delamination involves the feeding of an adhesive tape to the delaminating device, the actual delaminating process and the separate winding of the two components of the adhesive tape that have been separated as a result of the delaminating.

All three railway routes are independently train-controlled.

Such laminates can be produced in a wide variety of ways; possible production forms are described in detail, for example, in DE 10 2008 038 595 A1, which has already been mentioned. In each of the processes described there for the production of double-sided adhesive tapes, at least one delaminating process is necessary, which according to the present invention now takes place in a significantly more flexible, more economical and error-free reproducible manner.

The requirements for a symmetrical, ideal delaminating device are as follows:

- Since the process liner can be on both sides of the adhesive tape, it must also be possible to delaminate both sides of the adhesive tape equally well and reliably, i.e. symmetrical delamination must be possible.

- For this purpose, the same winding possibilities must be given on both sides without touching the partially uncovered adhesive layer with system components such as deflection rollers. Basically, a contact with a z. B. anti-adhesive equipped deflection roller possible. However, this can e.g. B. in the case of very adhesive adhesives lead to increased rejects or damage to the anti-adhesive finish of the roll.

- The delamination must be able to equally reliably and correctly delaminate different types of adhesives with different properties (softer or harder, more tacky or less tacky, more cohesive or less cohesive) from different types of backing materials with different dehesive finishes.

Ideally, the delaminating angle should be individually adjustable to the special features of the components to be delaminated, ie in general it should be as large as possible Delamination angle aimed at to avoid errors such as "chattering" (i.e. delamination with alternating sometimes abruptly varying delamination speeds) or unintentional "lifting" (e.g. punctiform or flat unintentional lifting) of the adhesive tape to be dismantled or its components (liner , carrier, adhesive sheet) to avoid. Such errors always occur when, for example, the liner and the adhesive surface are not completely separated from one another and thus detached from one another, but are still in close proximity to one another over a certain distance and time.

Another point to consider when delaminating is the fact that the adhesive layer, once applied to the liner or backing, may still be at a potentially higher temperature when it comes to the delaminating apparatus. High temperatures of up to 180° C. can impair the separating power of the silicone layer of the release liner or the carrier material, and it must also be possible to cleanly delaminate adhesive layers of different thicknesses with different temperatures and thus different delaminating requirements depending on their individual requirements, i.e. the delaminating device must be flexible be adjustable to these individual requirements.

At higher coating speeds z. B. 200 m / min there is always a high risk of static charging of the web. These charges can be > 20 KV and damage the silicone layer required to separate the layers, which of course also has an impact on the delaminating process and can have a negative impact on it.

Finally, before, during and after delamination, the aim is for the individual webs (adhesive tape, liner, carrier) to run as straight as possible in order to avoid sharp kinks and thus potential sources of error.

The process of delaminating described below now fully meets the above requirements:

In the first step, the arrangement to be delaminated (e.g. in the form of an adhesive- layered process liner or a carrier material remaining in the finished adhesive tape with the adhesive mass coated thereon, which is now covered by a release liner to be delaminated) via a permanently installed and therefore non-changeable suction puller, not shown in FIG - Roller fed to the actual delaminating unit via a lay-on roller (1) on a control frame. The feed to the lay-on roller (1) can take place from two directions (aA, bB), ie the composite and thus also the process liner can be guided around the lay-on roller (1) on one side or the other. This roller (l) is vertically linearly adjustable in order to be able to set the angle of wrap on the calender shaft (2) individually to the respective requirements - this means that the angle of wrap of the web to be delaminated around the calender shaft (2) can be changed, which means that a cooling capacity that may be necessary can be adapted to requirements. This in turn also affects the position of the other components involved in the delaminating process, ie these must be arranged or can be arranged so flexibly that they enable clean and reliable delamination from each of the two directions from which the process liner can flow . The arrangement of the machine components further involved in the delaminating process must therefore be symmetrically assignable (if the components are fixed and therefore no longer movable) or allow for symmetry (if the components are installed in such a way that they can be moved).

The arrangement to be delaminated is fed from the lay-on roller (1) to the countershaft (2), which is also permanently installed and therefore cannot be changed in its position; this is a temperature-controlled calender shaft. This countershaft (2) is connected to a delaminating roller, which can be pivoted 180° around the countershaft (2) (3a, 3b) and is adjusted to the individual delaminating requirements of the arrangement to be delaminated and to the delaminating direction at any angle between 0° and can take up 180°. The delaminating roller (3a, 3b) can of course also be permanently installed at any desired position within this 180° radius, or several such delaminating rollers can also be fixed at different positions within this radius be built in. However, this would significantly limit the complete flexibility of the angle and thus the possibility of many individually possible delaminating angles in which two layers are separated from one another. The delaminating roller (3a, 3b) in turn is directly connected to another roller which has the function of supporting the delaminating roller (3a, 3b) (support roller 4a, 4b) and thus stabilizing the delaminating process and making it reliably reproducible . This support roller can also be swiveled by up to 180°, but like the delaminating roller it can also be permanently installed at any position within this 180° radius or several such support rollers can also be installed at different positions within this radius . In principle, the support roller can be dispensed with. In this case, a larger delaminating roller must be selected for reasons of stability. However, this significantly limits the variability and the quality of delamination.

The function of the satellite roller (5a, 5b), which can be swiveled by up to 180° like the delaminating roller(s) (3a, 3b) and the supporting roller(s) (4a, 4b), is to separate the already delaminated components as far as possible from each other and at the same time to allow a further run to the respective winding station that is as separate as possible, in order to prevent kinks or other possible sources of error before or during winding. These roller(s) (5a, 5b) can also be mounted in the system in a fixed and non-pivoting manner.

Claims

- 9 - Claims:

1. Delaminating device for separating two layers connected to one another by an adhesive layer, one of which is a process liner or an adhesive tape carrier material, essentially consisting of:

- a lay-on roller (1)

- a tempered calender shaft (2)

- at least one delaminating roller (3a, 3b)

- At least one satellite roller (5a, 5b) and

- optionally at least one support roller (4a, 4b)

2. Delaminating device according to claim 1, characterized in that the delaminating roller (3a, 3b) can be pivoted by up to 180° around the calender shaft (2).

3. Delaminating device according to one of the preceding claims, characterized in that the support roller (4a, 4b) can be pivoted by up to 180° around the delaminating roller (3a, 3b).

4. Delaminating device according to one of the preceding claims, characterized in that the satellite roller (5a, 5b) can be pivoted by up to 180° around the calender shaft (2).

5. Delaminating device according to claim 1, characterized in that the delaminating device contains at least one non-movable delaminating roller (3a, 3b), supporting roller (4a, 4b) and satellite roller (5a, 5b).

6. Delaminating device according to one of the preceding claims, characterized in that the process liner can be guided around the lay-on roller (1) on both sides, as a result of which symmetrical delaminating becomes possible in the further course of the delaminating process.

7. Delaminating device according to one of the preceding claims, characterized in that the angle of wrap of the web to be delaminated around the calender shaft (2) can be changed by possible linear vertical displacement of the laying rollers (1), with which a possibly necessary cooling capacity can be varied.