Research

Research Topic

Mixing of disperse systems (particles and powders) is a traditional unit operation of process engineering which is of central importance in various technological areas. Applications of mixed particulate systems range from processing of food, pharmaceutical and chemical substances to material processing and materials engineering. Functional mixing of different particle types (hetero-aggregation) has the potential of creating outstanding new properties of dispersed products, which depend on the mixture composition (for example number of components, concentration, total quantity) and on various secondary process conditions (for example agglomeration, coating).

In this context, a new product property can emerge from the direct contact of different particles (hetero-contact) and thus by the resulting interface between the respective particular components. Many applications have shown that these hetero-contacts are of fundamental importance for specific functional properties. In most cases the new properties result from the transfer of charges, mass, heat, forces, or moments without the need of a chemical reaction of its components. Thus, the quality of such a particulate mixture is directly linked to the contact points and interfaces of different particles and the details of the interaction between its species in contact.

The new property from the contact zone controls the material and product properties of the entire system that is named hetero-contact in the context of the Priority Programme. Direct information about hetero-contact quality (for example number of contacts, transport properties between different particle types) could therefore be the base for a fundamental description of the new properties of the particle mixture (quality of the mixture and material function). At the same time, the hetero-aggregation process for creating of such hetero-contacts needs to be investigated and controlled.

    Jemand schaut mit einem Auge durch ein trichterartiges Bauteil

    Our goals

    The technical main goals and development areas of the Priority Programme are

     

    • the development of sophisticated methods for the characterisation of hetero-aggregates in disperse systems,
    • the development of suitable process diagnostics that feature component-specific detection,
    • the derivation of proper process descriptions and simulations with validated models (particle, continuum and/or population based) for mixtures of < 1 ?m sized particle systems, and
    • the establishment of efficient model couplings (e.g. DEM-CFD) for the ab-initio gas phase process design.

     

    These goals aim to a fundamental understanding of the relevant mixing phenomena on length scales in the sub-micrometre range and their modelling as well as transfer into applications of tailored hetero-aggregated particulate systems and aggregation processes.

     

    The processes for designing hetero-aggregates are divided into the formulation (from existing particle systems) and the production (from molecules and their reaction products) of the hetero-aggregates. The solely focus of the programme is on processes in the gas phase, where both adhesion forces and specific charge distributions of particles play an important role. Gas-phase aggregation processes can be implemented with different methods and reactor concepts.

    1st Phase

    2021 - 2024

    In the first three years of SPP 2289, the recursive approach dominated, adapting the material system of heteroaggregates to the process measurement technique and the characterisation methods of heteroaggregates and their populations. Special focus has been:

    • on the establishment of aerosol processes for the defined generation of heteroaggregates, which can also be adapted to process diagnostics for the detection of mixing processes < 1 μm,
    • the derivation of particulate sample trains from fast aggregation processes, the establishment of tomographic methods for the characterisation of heteroaggregates with sizes < 1 μm and - their mathematical basis for the description of heteroaggregates as well as
    • the establishment of process models and simulations that cover mixing lengths <1 μm.

    2nd Phase

    2024 - 2027

    In the remaining three years of the SPP 2289, research will increasingly focus on specific material functions of the heteroaggregated particulate systems, which will be verified and linked to the process parameters. This focus in turn places special demands on adapted process measurement and control techniques as well as on material and particle characterization. In detail, the SPP2289 has the following objectives:

    • Utilization of previous findings for multi-stage processes for the production of hetero-aggregates with integrated process control. This includes aerosol processes for the defined generation of hetero-aggregates, with adequate process diagnostics for the detection of mixing processes.
    • Utilization and coupling of various CFD, particle and reaction models and development of a holistic simulation environment for the design of material functions.
    • Establishment of standard procedures for the characterization of heteroaggregates in the sub-micrometer range using sample trains from rapid aggregation processes and tomographic methods for the characterization of heteroaggregates.