DE102007009680B4 - Method for characterizing the mechanical properties of specimens of PVC material to be compared - Google Patents

Abstract

Method for characterizing the mechanical properties of specimens of PVC material to be compared with the following method steps:
- Preparation of at least two samples of PVC material to be compared;
- Applying a sinusoidal mechanical stress on the sample bodies with changing the temperature of the sample body;
- Measurement of the sinusoidal load on the specimens;
Determination of the loss factor tan δ of the specimens as a function of the temperature, the phase angle δ corresponding to the phase shift between the sinusoidal load signal and the load action signal resulting therefrom on the specimen;
Determination of the at least two maximum values of the loss factor tan δ of the specimens to be compared for the characterization of the mechanical properties of the PVC material,
Relative comparison between the maximum values of the loss factor tan δ of the specimens, whereby better mechanical properties are assigned to the specimen with the respectively higher maximum value of the loss factor tan δ.

Description

The The invention relates to a method for characterizing the mechanical Characteristics of samples of PVC material to be compared according to the Teaching of claim 1.

polyvinylchloride (PVC) is behind polyethylene in the global consumption of plastics and polypropylene in third place with about 20 percent of the world Plastics production. Most PVC applications are attributed to the Construction sector and in particular the production of window profiles and pipes. To be PVC materials very high quality requirements posed. For example, PVC plastic windows become one Life expectancy of more than 50 years. The quality of PVC material, especially window profiles, must therefore constantly in Framework of quality assurance measures while tested the production become.

The Determination of mechanical properties of PVC material is in Quality assurance framework from very big Importance. To determine the mechanical properties of PVC material can usual mechanical test methods, for example, the exam the impact resistance, carried out become. These mechanical test methods However, they have the disadvantage that they are extremely time-consuming and costly and therefore, in particular, a fast production-accompanying test for Securing the mechanical properties is not possible.

Around bypassing the known mechanical test methods nevertheless the mechanical properties PVC material is commonly used in PVC production Geliergrad the PVC material as a measure to characterize the mechanical properties of the PVC material used. studies have shown that the optimal mechanical properties for a window profile usually with a degree of gelation of 70% to 80% (depending on the PVC recipe) lie. When setting an extrusion line to extrude the PVC material is this system therefore possible parameterized so that a corresponding degree of gelation of the extruded PVC material results.

adversely on the characterization of the mechanical properties of the PVC material the degree of gelling is that for determining the degree of gelling the O-DSC test method (Oscillating differential dynamic thermal analysis) usually used becomes. This O-DSC test method allows the gelling of the PVC material without prior calibration to eat. The O-DSC analysis is used oscillatory, to the PVC material regarding the experimental evaluation of other components of the compound, e.g. B. after chlorinated polyethylene, during the To separate measurement. A large Disadvantage of the O-DSC analysis for the characterization of the mechanical Properties of the PVC is that the process is extremely expensive and time consuming. In particular, the test chamber of the corresponding Analyzer after Approximately 50 to 100 measurements carefully cleaned or replaced, since the PVC samples in the DSC analysis up to 300 ° C heated must be, so that the PVC material is decomposed and forms aggressive substances. About that In addition, environmentally harmful substances such as hydrogen chloride, emitted and the measurement takes a relatively long time, as it oscillates expires. The results of the O-DSC analysis are not sufficient Accuracy reproducible, and the measurement results are not very exactly, as in a Geliergradbereich between z. Eg 70% and 80% the mechanical properties no longer exactly with the gelling correlate.

The DE 197 07 968 A1 describes a method and a device for investigating the mechanical-dynamic properties of workpieces, which in particular can also be made of a polymer. The basics of the hysteresis measurement are explained and explained that with polymer work pieces by DMC measurements statements regarding the damping behavior, the stiffness behavior and the non-elastic deformation behavior are possible. A laser light measuring device serves to measure the deformation on the specimen. Furthermore, it is explained that during the experiment also heating or cooling of the workpiece can be carried out in order to determine the temperature dependence of the measured values measured under vibration load.

The DE 39 18 835 describes methods for determining dynamic characteristics of elastic polymers as a function of the temperature. In particular, the loss factor tan δ of polymers can then be measured as a function of the temperature.

outgoing from this prior art for testing PVC materials in view on their mechanical properties, it is the task of the present Invention to propose a new method by which the mechanical Properties of the PVC material can be significantly characterized and which are at the same time simple, fast and inexpensive can.

These The object is achieved by a method according to the teaching of claim 1 solved.

advantageous embodiments The invention are the subject of the dependent claims.

to execution the method according to the invention have to first at least two specimens be made of the PVC material. These specimens will be then in a testing machine a sinusoidal subjected to mechanical stress, coinciding with the sinusoidal mechanical Load the temperature of the sample body is changed, including the sample body, for example can be heated.

With According to suitable measuring sensors are those of the mechanical Load generated sinusoidal Load effect on the specimens measured. For this example, the deformation or the voltage in the specimen be measured as a response signal. Regarding the input signal (Sinusoidal mechanical load) and the response signal generated thereby respective sample body (Sinusoidal Load effect) become the amplitude and the phase shift evaluated between the two signals. Depending on the material properties of the PVC material results in characteristic phase shifts, measured with the phase angle δ and be specified. The phase angle δ characterizes the phase shift between the dynamic stress and the dynamic deformation a viscoelastic material exposed to a sinusoidal load is.

Out the phase angle δ can then for every sample the loss factor is calculated as tan δ with the loss factor being the ratio between loss and Memory module of the material features. The loss factor tan δ usually becomes as a measure of the energy losses used in a vibration related to the recoverable energy. It indicates the mechanical damping or internal friction a viscoelastic system. A high value of tan δ marks So a material with high non-elastic deformation part; a low value for tan δ marks a more elastic material.

There the specimen while the sinusoidal As its temperature changes, mechanical stress also changes measured loss factor tan δ. While the measurement for the samples to be compared is therefore continuously or at certain intervals the respective loss factor tan δ determined, so that within the given temperature band, a measurement curve for the loss factor tan δ yields. As soon as the entire temperature band has worn off and the resulting resulting trace of tan δ is recorded, the maximum value of the loss factor tan δ is determined in this measuring range.

Of the to be determined maximum value of the loss factor tan δ is less suitable, as an absolute value for characterization the mechanical properties of the PVC material. Therefore, according to the invention a relative comparison between the maximum values of the loss factor tan δ for the different ones specimen carried out. For each becomes the sample to be compared Thus, the maximum value of the loss factor tan δ determined, the sample body with the higher one Maximum value to be assigned the better mechanical properties. That way you can different materials from which made the respective specimens are simply compared in terms of their mechanical properties become.

scientific Studies have indeed shown that the mechanical properties of the PVC material, for example, tensile strength and impact resistance, Characteristic with the maximum value of the loss factor tan δ in the temperature range correlated between -50 ° C and 150 ° C. This in other words means that a PVC material with a high Maximum value for the loss factor tan δ accordingly has better mechanical properties than a material with a lower maximum value for the loss factor tan δ.

to execution the method according to the invention can resort to the DMA analysis (dynamic-mechanical analysis) become. The DMA provides information about the course of mechanical Properties under low, sinusoidal dynamic load as a function of temperature, time and / or frequency.

In determining the loss factor tan δ, known analysis methods can be used to determine the phase angle δ in a simple manner. In particular, it is advantageous if, during the measurement, the resulting complex module is determined according to DIN EN ISO 6721-1 and this complex module is divided into memory module E 'and loss modulus E ". The memory module E 'and the loss modulus E "are dynamic-elastic parameters. The storage modulus E 'represents the stiffness of a viscoelastic material and is proportional to the maximum work elastically stored during a loading period. In contrast, the loss modulus E "is proportional to the work dissipated in the material during a loading period. The phase angle δ can be derived from the measured values E 'and E ". The type of sinusoidal mechanical stress in the test of the specimen is basically arbitrary and abzustim on the particular application men. Experiments have shown that a sinusoidal mechanical stress with a tensile load, occur in the deformations in the range of 3 microns to 20 microns, especially 5 microns, is particularly well suited to the mechanical properties of the PVC material determined by the maximum value of the tan δ to characterize.

Farther it is particularly advantageous if the sinusoidal mechanical stress with a frequency in the range of 0.1 Hz to 10 Hz, in particular approximately 1 Hz, on the specimen is applied.

Of the specimen itself can ultimately have any geometry. When Sample bodies with a width of 10 are particularly suitable mm and a minimum length of 40 mm proved. The specimen thickness depends on the production requirement of the PVC material.

Of the specimen is during the measurement of the loss factor tan δ in a temperature range heated. This temperature range is determined by a minimum temperature, especially room temperature, and a maximum temperature, for example 100 ° C, defined.

Especially simply can be measured when the specimen from a minimum temperature than Start temperature to a maximum temperature as the final temperature, for example 100 ° C, heated becomes. The warming can be done either continuously or in temperature stages.

To In a preferred variant of the method, the temperature during the Measurement with a heating rate in the range of 1 K / min to 10 K / min, especially 5 K / min, increased.

Around Scattering effects when measuring the maximum value of the loss factor tan δ too minimize the maximum value in several independent single measurements, for example, three times in succession. From these Single measurements can then be provided for further processing maximum value of the loss factor tan δ as Average value of the various individual measurements can be determined.

From of particular value is the comparison of the mechanical properties, if the samples to be compared in each case different chemical PVC formulations, in particular different additive compositions, exhibit. With the implementation of the rapid test according to the invention, the PVC formulations are very accurately and easily optimized. For example can costly additives are reduced as far as the mechanical Properties significantly opposite Materials with higher Drop additive concentration. It is also possible that the share is cheaper Additives, in particular fillers, is increased, as long as the mechanical requirements for the profile are still met.

Big influence also have on the mechanical properties of the PVC material the extrusion conditions under which the PVC material extrudes has been. To the extrusion of the PVC material with regard to To optimize mechanical properties can therefore be compared specimen each have the same chemical PVC formulation but with different extrusion conditions, for example, with different extrusion temperatures, extruded have been. That way you can the optimal extrusion conditions are found.

The biggest economic Importance PVC materials have in the production of profiled bodies, in particular in the manufacture of window profiles or pipes.

The mechanical properties of the PVC material can thereby still by the Hang the position of the material in the respective profile body. To the profile geometry in terms of That is why it is special to be able to optimize the mechanical properties advantageous if the samples to be compared from the same profile body taken from different positions of the profile body. Thereby can be achieved that it is as uniform a level as possible which gives properties at all positions of the profile body.

following the basis of the method according to the invention is based on various measurement diagrams be set out.

It demonstrate:

1 a measurement diagram for determining the loss factor tan δ from the memory module E 'and the loss modulus E'';

2 the characterization of the mechanical properties of two PVC specimens as a result of the measurement of the maximum values of the loss factor tan δ;

3 the correlation between the maximum value of the loss factor tan δ and the impact resistance as a function of the extrusion temperature.

1 shows a typical measurement diagram for determining the loss factor tan δ using the DMA analysis (dynamic mechanical analysis). The DMA provides information about the history mechanical properties under low sinusoidal dynamic stress as a function of temperature, time and / or frequency. The storage modulus E 'and the loss modulus E "are derived from the measured load effect signals on the sample body using known analysis methods. From the relationship between E '' and E 'then the loss factor tan δ results. How out 1 can be seen, the maximum value of the loss factor tan δ in the glass transition of about 90 ° C. This maximum of the loss factor tan δ characterizes the relative mechanical properties of the investigated PVC material.

2 shows the curves of the loss factor tan δ for two different PVC samples. The maximum value of the loss factor tan δ is for the sample 1 significantly higher than for the sample 2 , Therefore, according to the invention, it can be assumed that the mechanical properties of sample 1 better than the mechanical properties of sample 2 are. Meadows sample 1 and sample 2 For example, different additive concentrations, so could the additive composition of sample 1 better than the additive composition in the sample 2 be accepted. Or were sample 1 and sample 2 extruded at the same PVC formulation under different extrusion conditions, so the extrusion conditions of sample 1 as better against the extrusion conditions of sample 2 be accepted.

In 3 are the maximum values of the loss factor tan δ and the respective associated tensile tensile strength of specimens presented, which have been extruded with different extrusion temperature. It can be seen that the optimum extrusion temperature is between 195 ° C and 200 ° C, since the mechanical properties, as characterized by the impact toughness, reach their maximum in this range. The measured values for impact tensile strength are in 3 are plotted as circle points, whereas the measured values of the maximum values of the loss factor tan δ are shown as square points.

comparing the course of impact toughness over the Extrusion temperature with the course of the loss factor tan δ over the Extrusion temperature, it can be seen that both are characteristic of each other correlate and each reach their maximum in the range of 195 ° C to 200 ° C. In this respect, the assumption is justified that the mechanical properties of the PVC material, here for example depending on the respective Extrusion temperature, with the measurements of the maximum loss factor tan δ correlate.

Claims (13)

Method for characterizing the mechanical Characteristics of samples to be compared made of PVC material with following process steps: - Production of at least two samples to be compared made of PVC material; - application a sinusoidal mechanical stress on the specimens under change the temperature of the specimens; - Measurement the sinusoidal Load effect on the specimens; - Determination the loss factor tan δ the specimen dependent on from the temperature, wherein the phase angle δ of the phase shift between the sinusoidal Load signal and resulting therefrom on the sample body load effect signal corresponds; - Determination the at least two maximum values of the loss factor tan δ of the to be compared specimen for characterizing the mechanical properties of the PVC material, - Relative comparison between the maximum values of the loss factor tan δ the sample body, wherein the specimen with the higher one Maximum value of the loss factor tan δ better mechanical properties be assigned. Method according to claim 1, characterized in that that the loss factor tan δ is off the relationship between the loss modulus E "and the memory module E 'is derived. Method according to claim 1 or 2, characterized that the sinusoidal mechanical load as tensile load with a deformation in the range of 3 μm up to 20 μm, in particular 5 μm, on the specimen is applied. Method according to one of claims 1 to 3, characterized that the sinusoidal mechanical load with a frequency in the range of 0.1 Hz to 10 Hz, in particular 1 HZ, is applied to the sample body. Method according to one of claims 1 to 4, characterized that the sample body a Width of 10 mm and a minimum length of 40 mm. Method according to one of claims 1 to 5, characterized that the loss factor tan δ in a temperature range between a minimum temperature, in particular Room temperature, and a maximum temperature, in particular 100 ° C determined becomes. Method according to one of claims 1 to 6, characterized in that the temperature currency is increased during the measurement between the minimum temperature as start temperature and the maximum temperature as the end temperature continuously or in temperature stages. Method according to one of claims 1 to 7, characterized that the temperature during the measurement with a heating rate in the range of 1 K / min to 10 K / min, in particular 5 K / min, is increased. Method according to one of claims 1 to 8, characterized that for determining the maximum value of the loss factor tan δ several, especially three, independent Single measurements performed with the maximum value of the loss factor tan δ as the Average value of the maximum values measured in the various individual measurements is defined. Method according to one of claims 1 to 9, characterized that to be compared specimen each different chemical PVC formulations, in particular different additive compositions. Method according to one of claims 1 to 9, characterized that to be compared specimen each have the same chemical PVC formulation and through distinguish different extrusion conditions in which the PVC material of the samples to be compared has been extruded in each case is. Method according to one of claims 1 to 9, characterized that to be compared specimen from the same profile body have been taken and reflected by the different position in the profile body differ. Method according to one of claims 1 to 12, characterized that the PVC material is material for production of profile bodies, especially window profiles or pipes.