Abstract
Membrane emulsification is a promising new technique that can be deployed as a scalable modular conduit for the consistent and continuous production of single and complex emulsions. This work reports on the development of a manufacturing platform based on membrane emulsification for the first time for microcapsule-based self-healing cementitious materials. The feasibility of single and double emulsion production with wall formation as a secondary step through UV radical polymerisation was explored using a discrete membrane emulsification dispersion cell. The operational parameters (pressure, dispersed phase flux, temperature, shear rate) were established for the specific phase characteristics (viscosity, density, interfacial tension) to achieve control of emulsion droplets and maintain a high encapsulation of core content (high payload). Microcapsules with sodium silicate core and an average diameter of ∼130 μm were produced. Microcapsules were shown to achieve high payload (∼89%). Moreover their thermal stability was characterised and their release performance in the cementitious matrix established. The results demonstrated the capability of membrane emulsification to produce microcapsules with an aqueous core for use in self-healing of cementitious materials.
Highlights
One of the most exciting and fledgling trends in material innovation that is set to revolutionise infrastructure are biomimetic and in particular self-healing materials [1, 2]
The results demonstrated the capability of membrane emulsification to produce microcapsules with an aqueous core for use in self-healing of cementitious materials
We investigated the influence of the surfactant content, viscosity of continuous phase, dispersed phase flux and agitation speed on the emulsion characteristics and particulate formation
Summary
One of the most exciting and fledgling trends in material innovation that is set to revolutionise infrastructure are biomimetic and in particular self-healing materials [1, 2]. Encapsulation through traditional bulk emulsion approaches is hard to control and can lead to polydisperse systems [17] The latter can affect the polymerisation/wall formation process and further hinder equal dosing of the active ingredient in the formed microcapsules [18]. Significant effort has been dedicated into optimisation of the droplet breakdown procedures in terms of emulsification process scale-up Within this remit production of emulsions using drop-by-drop approaches is of growing interest as it allows greater control over droplet size distribution and properties [19]. The distinguishing features of the latter deviating from traditional technologies is that rather than continuously breaking down droplets to smaller sizes till the final required size is achieved, each droplet is produced individually with the final desired dimensions
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