DE20014891U1 - Measuring device for determining the viscoelastic properties of PSAs, especially in thin layers - Google Patents

Description

Beiersdorf Aktiengesellschaft Hamburg

Description Measuring device for determining viscoelastic properties of pressure-sensitive adhesives

especially in thin layers

The invention relates to a measuring device for determining viscoelastic properties of pressure-sensitive adhesives as well as of technical or medical self-adhesive tapes.

The characteristics of adhesives can be determined by measuring certain parameters, for example the adhesive strength on steel using the wall hook test, the test setup of which is described in more detail below and which is used to test the high mechanical resilience of a double-sided self-adhesive tape.

The self-adhesive tape is subjected to a bending moment using a stamp-shaped wall hook. The wall hook consists of a square steel plate made of V2A steel with an edge length of 30 mm and a thickness of 3 mm. A round rod is attached to the middle of the steel plate as a lever arm, which is 90 mm long and 5 mm in diameter. The steel plate is glued to a second steel plate made of V2A steel using the self-adhesive tape to be tested. The second steel plate is located in a correspondingly shaped holder.

At the point which is exactly 90 mm away from the glued side of the steel plate of the wall hook, a weight is hung on the round rod, which generates a leverage force of 10 N.

pat-st/200-019-gm.doc/ar

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The bonded surfaces of the steel plates must be completely flat and finely sanded using sandpaper (FEPA grain 240). To preserve the surface and avoid traces of grease on the surface, the steel plates must be stored in toluene. Before use, the steel plates must be cleaned with acetone and then aired for five minutes.

Before starting the wall hook test, the self-adhesive tape must be conditioned for 24 hours at a temperature of 22 ⁰ C and 55 % relative humidity.
The steel plate is glued to the steel plate using the precisely cut self-adhesive tape to be tested and pressed flat for 1 minute with a pressure of 0.1 kN/cm ² .

The holding time in minutes is determined at 55% relative humidity and three temperatures of 22 ⁰ C, 40 ⁰ C, 70 ⁰ C. In addition to the holding time, the deformation of the self-adhesive tape is assessed.
If one of the bonds between the self-adhesive tape 2 and the steel plates fails, the wall hook falls down along with its weight. This closes a contact in a contactor, so that the time between the start of the test and the failure of one of the bonds - the holding time - is precisely displayed.

A comprehensive assessment of the adhesive properties of pressure-sensitive adhesives and the products made from them is hardly possible using a measuring method alone.

Rather, a targeted selection of several suitable measuring methods makes it possible to determine the required product property profiles. Muny (Muny, R.P.: Adhesives Age 39/8, 20/1996) describes a selection of suitable measuring methods for the properties of bonding to steel, shear life and tack.

The adhesive properties of pressure-sensitive adhesives are determined in particular by their rheological properties (see Macosko, CW.: Adhesives Age, 35 - 37, Sept. 1977). During the development, evaluation and quality control of pressure-sensitive adhesives and products made from them, the measurement of the rheological properties is therefore of great importance.

The measurement of adhesive strength on steel, shear time or tack also capture theological parameters to a certain extent, but mix these with adhesion and surface structure effects.

For example, by measuring the shear strength, not only the shear strength itself can be determined, but also, in the case of a purely cohesive adhesive failure (pure cohesive failure), a statement can be made about the viscous properties of a pressure-sensitive adhesive under the selected test conditions. In practice, however, the measurement result of the shear strength is often mixed up with the adhesion properties of the sample to the sample carrier, so that the shear strength distinguishes between cohesive and adhesive failure.

Another measuring method for determining the rheological properties of a pressure-sensitive adhesive is the creep test (see Dahlquist, CA.: Creep in D. Satas: Handbook of PSA Technology, 2nd ed., 1989), which examines creep behavior such as yield point or flow behavior under small loads. However, sum parameters of elastic and viscous flow components are again determined.

Separating these different influences is possible by increasing the amount of equipment required using dynamic mechanical analysis (DMA) (see Brummer, R., Harder, Ch., Hetzel, F.: Correlation of polymer properties with dynamic mechanical measurement results; Applied Rheology, Vol. 7, August 1997, pp. 173 - 178 and Sung Gun Chu: Viscoelastic Properties of Pressure Sensitive Adhesives in D. Satas: Handbook of PSA Technology, 2nd ed., 1989). DMA enables statements to be made about the viscoelastic flow behavior using a defined sample geometry and a defined load on the sample. Disadvantages of this method are the complex sample preparation, since the samples to be examined must have a certain minimum layer thickness, and the large amount of equipment required, which is associated with corresponding costs.

The object of the invention is to provide a measuring device which enables the measurement of viscoelastic properties of a pressure-sensitive adhesive with little equipment expenditure and, moreover, also allows the measurement in a thin layer.

This object is achieved by a measuring device as characterized in the claims. Furthermore, the inventive concept includes advantageous embodiments of the measuring device.

Accordingly, the invention describes a measuring device for measuring viscoelastic properties of pressure-sensitive adhesives, comprising two parallel plates which can be moved parallel to each other.

A test sample of a pressure-sensitive adhesive is present between the panels.
By applying a constant tangential force to one of the plates while fixing the second plate, a constant shear stress is achieved.
Then the shear deformation angle resulting from the shear or a value that makes the shear deformation angle calculable is recorded in the device.

According to the invention, the object is also achieved by a measuring device for measuring viscoelastic properties of pressure-sensitive adhesives, comprising a plate and a parallel arranged flat structure, in particular a textile fabric, a plastic or metal film or a fleece, which can be moved parallel to one another.
The test sample of the pressure-sensitive adhesive is present between the board and the fabric.

A constant shear stress is achieved by applying a constant tangential force to one plate while fixing the parallel arranged surface structure.

The shear deformation angle resulting from the shear or a value that makes the shear deformation angle calculable is recorded in the device.

In a preferred embodiment, defined constant or defined variable environmental conditions such as temperature, pressure, humidity and pre-loads of the sample are maintained.

The constant shear stress to be determined can preferably be selected such that the shear deformation angle generated does not exceed 85°, preferably 45° and particularly preferably 10°.

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Furthermore, the thickness of the sample volume examined or of the sheared pressure-sensitive adhesive orthogonal to the shear surface should be less than 2000 \xm, preferably less than 500 pm and particularly preferably less than 150 pm.

The evaluation of a measurement is carried out in such a way that the function of the shear deformation angle generated in the manner described is mathematically described as a function of time by mechanical substitute models whose parameters can be correlated with certain viscous, elastic and static friction properties. Models that mechanically represent the viscous and elastic properties of the sample under investigation are preferred, the Burger model is particularly preferred, consisting of two ideally viscous elements A1 and A2 and two ideally elastic elements B1 and B2 (see Figure 6).

By applying a constant tangential force to one of the plates while fixing the second plate or by applying a force to the plate while fixing the surface structure, a constant shear stress is generated in the sample to be examined.
If necessary, the surface structure must be reinforced with a suitable material in order to distribute the tangential force evenly into the sample.

Further devices ensure that the resulting shear deformation angle can be recorded at any time during the process and that defined environmental conditions can be maintained or adjusted by, among other things, air conditioning.

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In an advantageous embodiment of the measuring device, the measuring process and the control of the measuring device with an evaluation unit are carried out by a) sample preparation with suitable aids b) loading the measuring device with the sample

c) Entering the measurement parameters

d) appropriate conversion of the measurement parameters into control sequences for the measuring device

e) Feedback of the measured variable to the evaluation unit as a function of time f) Evaluation of the measurement results

g) Storage and logging of measurement parameters and results

In the following, the measuring device according to the invention will be explained in more detail using several examples and figures, without wishing to unnecessarily limit the invention.

In detail, the figures show

Figure 1 shows the shear of a pressure-sensitive adhesive layer under constant

Burden,

Figure 2 (a) a non-ideal shear due to slip,

(b) non-ideal shearing due to peeling,

Figure 3 a non-ideal shear due to excessive deformation,

Figure 4 an example of the response function of the shear angle over time

and

Figure 5 shows the device for ensuring a defined geometry.

example 1

Method for measuring viscoelastic properties of technical and medical pressure-sensitive adhesive products

Sample preparation includes cutting the flat product to be tested, consisting of a carrier material and a pressure-sensitive adhesive coating on at least one side, to a size of 20 x 160 mm and sufficient conditioning in the test climate. The sample is then bonded to a steel plate with a defined pressure and subjected to a constant shear stress, which - while the steel plate is fixed - is generated by a constant force on the carrier material of the sample in the direction of the bonding plane (see Figure 1), preferably in such a way that an angle of between 0° and 3° is set between the force generating the shear stress and the bonding plane, so that no peeling force occurs.

During the measurement period, the shear deformation angle γ (see Figure 1) is measured and recorded at defined time intervals using suitable measuring methods.

The surface of the steel plate must be prepared in such a way that the pressure-sensitive adhesive does not slip or peel off (see Figure 2); the influence of non-ideal shear (see Figure 3) must also be excluded or, if necessary, taken into account in the calculation.

The result of the measurement is, for example, a response function of the shear deformation angle over time as shown in Figure 4.
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An application of the Burgers model to this response function provides, after mathematical adjustment, the parameters of the Burgers model, which can be correlated with viscous and elastic properties of the material under investigation.

Example 2 Method for measuring viscoelastic properties of pressure-sensitive adhesives

A pressure sensitive adhesive is applied as a dispersion adhesive, hot melt adhesive, solvent adhesive or 100% system with a basis weight of 100 g/m ² on a pre-

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preferably spread on a rigid carrier material and, if necessary, dried or post-treated.
The further procedure corresponds to that described in Example 1.

Example 3 Measuring device for carrying out the method according to Example 1 or 2

The measuring device consists of a device for ensuring a constant geometry, such that a sample of cut carrier material ( 4) coated with a pressure-sensitive adhesive (3) is glued to a steel plate (2) with defined pressure and can thus be screwed vertically to a temperature-controlled steel block (1) (see Figure 5).
To generate a constant shear stress, the free end of the sample is loaded with a weight of defined mass using a suitable suspension. To ensure constant environmental conditions during the measurement, the measuring unit is shielded and exposed to the defined test climate. The shear deformation angle is observed as a function of time indirectly using suitable thickness measurements of the bonded sample and by measuring the distance that the upper edge of the carrier material travels in relation to the fixed steel plate. To ensure sufficient accuracy of the distance measurement, mechanical, electrical or optical distance measuring methods can be used, for example.
The requirements placed on the measuring devices with regard to the recording of measurement parameters, the conversion of measurement parameters into control sequences for the measuring devices, the feedback of the measured variables as well as the evaluation and logging of the measurement parameters, measurement results and evaluation results can be met by a connected PC system with suitable control and evaluation software.

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Claims (6)

1. Measuring device for measuring viscoelastic properties of pressure-sensitive adhesives, comprising two parallel plates which can be moved parallel to one another, a test sample of a pressure-sensitive adhesive being present between the plates, a constant shear stress being achieved by applying a constant tangential force to one of the plates while fixing the second plate, the shear deformation angle resulting from the shearing or a variable which makes the shear deformation angle calculable being recorded. 2. A measuring device for measuring viscoelastic properties of pressure-sensitive adhesives, comprising a plate and a parallel arranged flat structure, in particular a textile fabric, a plastic or metal foil or a fleece, which can be moved parallel to each other, wherein
the test sample of the pressure-sensitive adhesive is present between the board and the fabric,
a constant shear stress is achieved by applying a constant tangential force to one plate while fixing the parallel surface structure,
the shear deformation angle resulting from the shear or a quantity that makes the shear deformation angle calculable is recorded. 3. Measuring device according to claims 1 and 2, characterized in that the measuring process and the control of the measuring device with an evaluation unit are carried out by a) Sample preparation using suitable tools b) Load the measuring device with the sample c) Entering the measurement parameters d) appropriate conversion of the measurement parameters into control sequences for the measuring device e) Feedback of the measured variable as a function of time to the evaluation unit f) Evaluation of the measurement results g) Storage and logging of measurement parameters and results 4. Measuring device according to claims 1 to 3, characterized in that the measurement is carried out under defined and reproducible environmental conditions, for example temperature, pressure, humidity, pre-loads of the sample. 5. Measuring device according to claims 1 to 4, characterized in that the constant shear stress produces shear deformation angles after a constant measuring time of < 85°, preferably < 45° and particularly preferably < 10°. 6. Measuring device according to claims 1 to 5, characterized in that the thickness of the sheared pressure-sensitive adhesive orthogonal to the shearing surface is < 2000 µm, preferably < 500 µm and particularly preferably < 150 µm.