DE20111902U1 - Accelerated stability analysis - Google Patents

Description

Accelerated stability analysis

Description

The invention relates to the qualitative and quantitative direct determination/evaluation of demixing processes of disperse material systems (liquid-solid, liquid-liquid or liquid-gaseous), in particular to a device for the classification and quantitative characterization of slow as well as very fast demixing phenomena of disperse

&iacgr;&ogr; material systems of different volume concentrations. The main areas of application are in the development, selection and optimization of destabilizers, stabilizers and new formulations for dispersions as well as in quality and process control, e.g. in the chemical, pharmaceutical, biotechnological, cosmetic and food industries as well as in process engineering for separation and

is processing processes.

In general, a distinction must be made between indirect and direct methods for assessing the rate of separation phenomena of dispersions and for predicting stability.

What the indirect methods have in common is that different analytical methods are used to determine one or more material or dispersion parameters which influence the demixing behavior based on known basic physical laws (Stooke's law), such as density, size distribution of the dispersed particles or the rheological behavior. The disadvantage of all these methods is that Stooke's law was only derived under idealized conditions (e.g. extreme dilution) and therefore for practice-relevant, usually highly concentrated, complex material systems, the demixing rate cannot be calculated a priori, nor can the stability be predicted without additional comparative measurements, even with the complex determination of several relevant parameters.

The direct methods (centrifuge separation, gravitational separation) determine the separation speed via the local change in the composition of the dispersion as a function of time. For highly stable dispersions (very slow separation), for example, normal or analytical centrifuges (DE 4116313.3-52) are used.

. I

used. In this case, the demixing is greatly accelerated. In addition to a number of measurement problems (currently only solved for light transmission), dispersions that demix quickly cannot be examined with this method. Furthermore, the resulting centrifugal forces can lead to a change in the structure of the dispersion. A transfer to normal storage conditions is therefore not possible.

Dispersions that demix quickly enable assessment in the gravitational field. If the particles have migrated a sufficient distance due to the gravitational force, corresponding concentration changes can be detected. The so-called test tube test according to DIN 51599 is well known. Here, the height of the clear phase is measured by eye after a certain time.

&iacgr;&ogr;. However, the results are subjective and have an accuracy of only 0.5 mm. In order to ensure minimal documentation in this process, images are sometimes taken with still or digital cameras and archived accordingly. A method is also known in which the information in these images is subsequently quantified using image processing (Demulsibility Tester, Analis, Belgium). The disadvantages here are the relatively low spatial and temporal resolution, the dependence of the results on the absorption properties of the disperse and fluid phases (use of white light) and the lack of possibility of accelerating the demixing process. Methods for analyzing demixing are also known which use suitable sensors to register the concentration changes or structural changes that occur at predetermined locations on the dispersion sample. For this purpose, electrodes for determining conductivity (www.kruss.de) or optical detectors (cf. JP 5078236, US 4099871, US 4457624, DD 216104, DE-OS 3618707) are used. The main disadvantage of these methods is that the position of the sensors is fixed according to the method and therefore no information is available about the areas of the dispersion between the sensors. This severely limits the assessment of demixing processes in complex dispersions.
In the case of conductivity sensors, only conductive dispersions can be evaluated.
To avoid the above disadvantages, scanning sensor systems (e.g. scanning sedimentometers) are used (DE 3609552, AT 397159, EP 0760092, US 5783826). Here, the sensors are mechanically moved along the vertically positioned cuvette (or vice versa) and the measured values are recorded at discrete locations one after the other. Due to the process, it is therefore not possible to obtain an instantaneous image of the concentration profile or the local structure of the dispersion over the entire height of the cuvette.

Typically, scanning times of more than 20 seconds are specified. A repeat of the measurement is only possible after twice the scanning time. The analysis of rapid demixing changes is therefore only possible to a very limited extent. Secondly, the relative and absolute spatial resolution is determined by the mechanical design principle (step size). Resolutions of a few micrometers are accompanied by a disproportionate increase in technical and financial expenditure. Thirdly, with mechanical principle solutions with moving sensors or cuvettes, micro-vibrations, which are known to influence the kinetics of demixing phenomena, can never be completely excluded. Fourthly, the above methods are limited to vertical, cylindrical cuvettes with

&iacgr;&ogr; circular cross-section, and their inaccurate positioning is a common source of error.

Fifthly, all methods based on gravitational force require long measurement times, sometimes even months. This makes process-related quality control impossible.

The invention is based on the object of developing a device for classifying segregation phenomena with which the disadvantages inherent in the prior art can be overcome.
The object was achieved by providing a device according to the invention for the classification and quantitative characterization of slow as well as very fast demixing phenomena of disperse material systems of different volume concentrations.

The device according to the invention can be used to determine the stability or instability of a dispersion or to investigate stabilizing or destabilizing influences on a dispersion. Surprisingly, the invention provides a solution in particular which enables the instantaneous determination of the local composition of the dispersion over the entire height of the cuvette as well as its temporal change in tenths of a second intervals without movement of the cuvette, transmitter or receiver with respect to one another, with high spatial and temporal resolution. The invention is also based on the fact that the different volume concentration of the sample to be measured and the corresponding analysis objective can be taken into account by using measuring cells with different geometric dimensions without further changes to the device. Ultimately, the device according to the invention is designed in such a way that by tilting the

Measuring cell and transmitter/receiver without changing position, the demixing speed is accelerated without the influence of additional mechanical forces and thus, especially with more stable dispersions, the analysis time can be shortened several times and process-related quality controls become possible.

The features of the invention emerge from the elements of the claims and from the description, whereby both individual features and several in the form of combinations represent advantageous embodiments for which protection is sought with this document. The features of known and new elements in their entirety result in a synergistic effect which leads to the new device according to the invention

&iacgr;&ogr; leads to the determination of the stability and demixing of disperse material systems.

With the help of the solution according to the invention, it is surprisingly possible to carry out a qualitative and quantitative direct determination and/or evaluation of demixing processes of disperse material systems (liquid-solid, liquid-liquid or liquid-gaseous) with the highest temporal and spatial resolution, whereby an important feature of the invention is the additional gradual acceleration of the analysis process without the introduction of external energy (e.g. centrifugation). This is particularly important for gel-stabilized dispersions, for example.

The invention therefore consists in a device for determining the stability and demixing of disperse material systems, which contains tubular measuring cells and wave-emitting sources and receiving sensors. Its essence consists in the fact that a software-controlled device contains measuring cells of any cross-section for receiving the material to be measured, that in order to detect local and temporal changes in the composition of the material to be measured, one or more wave-emitting sources and receiving sensors are stationary with respect to the position of the respective measuring cell. They are arranged in such a way that the intensity distribution of the waves emerging from the sample is detected spatially and temporally over the entire height of the measuring cell by means of snapshots and that the arrangement allows the position of the cell and the sources and sensors to be changed with respect to the vertical force of gravity, but without changing their position relative to one another.

The device according to the invention contains both electromagnetic and acoustic sources and corresponding sensors as well as means which expand the point-shaped output radiation to the measuring cell height, parallelize it and direct it perpendicular to the

• » ·♦

Align the longitudinal axis of the measuring cell. The device consists of sources and sensors that are particularly linear in shape.

The measuring cells are made of different materials with circular, prismatic or rectangular cross-sections, which can vary along the longitudinal axis of the measuring cell. Thanks to a special design, several measuring cells can be analyzed independently of one another.

For the multi-station variant, the device according to the invention is controlled by the software from several identical measuring modules. For the multi-station variant, it contains appropriate means controlled by the software, such as mirrors, plane-parallel transparent plates, a lighting unit and/or a detector unit that analyzes different measuring cells.

The device according to the invention further contains additional devices by which

- the individual measuring stations are fed with the measuring cells asynchronously by hand or a robot

- the measuring cells are cleaned and repeatedly filled in situ by suitable means and controlled by software and the sample material is analyzed each time

- Means, such as racks, by which the measuring module with the measuring cell, the radiation source and the sensor is tilted relative to the vertical axis manually by means of a crank or controlled by the software by means of a stepper motor

- the measuring cells are connected to a circuit and are washed and repeatedly filled under the control of software and the sample material is analyzed each time.
Furthermore, the device according to the invention contains sensors which measure the current deviation from the vertical and whose measured values are retrieved by software and stored in the database and which are fixed separately from the measuring module.

Furthermore, heating and/or cooling elements as well as necessary temperature sensors for targeted temperature stabilization or for changing the temperature of the material being measured are available, as well as redispersion tools for homogenization before the start of the measurement.
Finally, the device according to the invention and the entire system are designed as a mobile measuring device.

In the following, the invention is described in detail without being limited to these examples.

A first typical design for the measuring method and the measuring station has the following structure:

The radiation source, the cuvette holder for holding different types of cuvettes and the line sensor are housed in a stable frame. The source, the cuvette's longitudinal axis and the line are located in one plane. If a point-shaped monochromatic electromagnetic radiation source is used, a convex lens, a half-cylinder lens or a lens system is used to generate parallel beam paths in the viewing plane perpendicular to the cuvette axis and line. According to the invention, NIR LEDs with wavelengths between 850 and 900 nm are used, the light of which is only emitted by the particles in the

&iacgr;&ogr; Dispersion scattered in a concentration-dependent manner (in the case of black particles also adsorbed) is used. However, sources of other wavelengths can also be used in combination.

A further embodiment is characterized as follows:
Instead of a point source, acoustic or optical line sources with a sufficiently small exit angle can also be used. The parallelism of the radiation incident on the measuring cell or the receiver line and thus the imaging of areas with changed concentration can be increased by thin lamellae which are arranged perpendicular to the cuvette's longitudinal axis and parallel to the cuvette's cross-section.

· · a

·

Claims (16)

1. Device for determining the stability and demixing of disperse material systems, which contains tubular measuring cells and wave-emitting sources and receiving sensors, characterized in that said software-controlled device contains measuring cells of any cross-section for receiving the material to be measured, that in order to detect the local and temporal changes in the composition of the material to be measured, one or more wave-emitting sources and receiving sensors are arranged stationary with respect to the position of the respective measuring cell in such a way that the intensity distribution of the waves emerging from the sample is detected spatially and temporally over the entire height of the measuring cell by means of snapshots and that the arrangement allows the position of the cell and the sources and sensors to be changed with respect to the vertical force of gravity, but without changing their position relative to one another. 2. Device according to claim 1, characterized in that it contains both electromagnetic and acoustic sources and corresponding sensors. 3. Device according to claims 1 and 2, characterized in that it contains means which expand the point-shaped output radiation to the measuring cell height, parallelize it and align it perpendicular to the longitudinal axis of the measuring cell. 4. Device according to claims 1 to 3, characterized in that it consists of sources and sensors, in particular of linear design. 5. Device according to claims 1 to 4, characterized in that it contains measuring cells made of different materials with circular, prismatic or rectangular cross-sections, which can vary along the longitudinal axis of the measuring cell. 6. Device according to claims 1 to 5, characterized in that it contains, by means of a special structure, several measuring cells which can be analyzed independently of one another. 7. Device according to claims 1 to 6, characterized in that it consists of several identical measuring modules for the multi-user variant controlled by the software. 8. Device according to claims 1 to 7, characterized in that it contains, for the multi-station variant controlled by the software by appropriate means, such as mirrors, plane-parallel transparent plates, a lighting unit and/or a detector unit which analyzes different measuring cells. 9. . Device according to claims 1 to 8, characterized in that it contains additional devices by means of which the individual measuring stations are fed with the measuring cells asynchronously by hand or by a robot. 10. Device according to claims 1 to 9, characterized in that it contains additional devices by means of which the measuring cells are cleaned and repeatedly filled in situ by suitable means and controlled by software and the sample material is analyzed in each case. 11. Device according to claims 1 to 10, characterized in that it contains additional devices by which the measuring cells are connected to a circuit and, controlled by software, are washed and repeatedly filled and the sample material is analyzed in each case. 12. Device according to claims 1 to 11, characterized in that it contains additional devices by means such as racks, by which the measuring module with the measuring cell, the radiation source and the sensor is inclined relative to the vertical axis manually by means of a crank or controlled by the software by means of a stepper motor. 13. Device according to claims 1 to 12, characterized in that it contains sensors which measure the current deviation from the vertical and whose measured values are retrieved by software and stored in the database and which are fixed separately from the measuring module. 14. Device according to claims 1 to 13, characterized in that heating and/or cooling elements as well as necessary temperature sensors are present for targeted temperature stabilization or for changing the temperature of the material to be measured. 15. Device according to claims 1 to 14, characterized in that redispersion tools for homogenization are integrated before the start of the measurement. 16. Device according to claims 1 to 15, characterized in that the system is designed as a mobile measuring device.